Market Analysis for API Vulnerability Scanner The API vulnerability scanner market is estimated to reach USD XXX million by 2033, growing at a CAGR of XX % from 2025 to 2033. The increasing adoption of APIs in various industries, coupled with the rising threat of API-based cyberattacks, is driving the demand for API vulnerability scanners. Growing awareness about API security and regulatory compliance requirements is also fueling market growth. The market is segmented by type (SQL Injection Scanner, Cross-Site Scripting (XSS) Scanner), application (SMEs, Large Enterprises), and region (North America, Europe, Asia Pacific, Middle East & Africa). Key players in the market include Astra, Intruder, API Insights, and APIsec. North America holds a significant market share due to the presence of numerous API-driven businesses and stringent data protection regulations. Asia Pacific is expected to witness the fastest growth, driven by the rapidly growing IT industry in the region. The market is expected to be challenged by factors such as the high cost of API vulnerability scanners and the shortage of skilled professionals in API security. However, the growing demand for automated security solutions and the increasing adoption of cloud-based API management platforms are expected to support market growth over the forecast period. Overall, the API vulnerability scanner market is poised for significant growth in the coming years, as organizations prioritize API security to protect their critical data and infrastructure.

🇫🇷 프랑스 English scanR, the research and innovation engine identifies more than 90000 project funding (ANR, FP7, H2020, PHC, PHRC, Casdar, theses Ademe, PIA, INCA, Innovation 2030, REACTing). The data presented are not exhaustive. Indeed, contrary to the terms of Law No 2016-1321 of 7 October 2016 For a Digital Republic, all data on public funding of research on call for projects is not accessible. scanR values and integrates all the data it accesses. In some cases, the information is accessible via databases or APIs made available by the data producer. In other cases, scanR only has information disseminated in an open manner on the website of the institution in charge of the financing. If the results of a funding agency are not included, scanR does not access the data or, given the quality of the information available, the cost of processing the accessible information is too high. All data to date (dump) are available for download at this address: ‘HTTPS://STORAGE.GRA.CLOUD.OVH.NET/V1/AUTH_32C5D10CB0FE4519B957064A111717E3/SCANR/PROJECTS.JSON’ These data are also accessible via the api de scanR.

The global API Vulnerability Scanner market is estimated to be valued at USD 923.6 million in 2025 and is projected to reach USD 2,567.7 million by 2033, exhibiting a CAGR of 12.5% during the forecast period. The increasing adoption of APIs in various industries, the growing number of API-based attacks, and the rising security concerns among organizations are the major factors driving the growth of the market. The market is dominated by North America and Europe, which account for a significant share of the revenue. The API Vulnerability Scanner market is segmented based on application, type, and region. By application, the market is divided into SMEs and large enterprises. By type, the market is categorized into SQL injection scanner, cross-site scripting (XSS) scanner, and others. By region, the market is segmented into North America, South America, Europe, Middle East & Africa, and Asia Pacific. The key players in the market include Astra, Intruder, API Insights, APIsec, Pentest-Tools, HostedScan Security, Radware, Nessus, Burp Suite, Acunetix API Security, Apidog, Postman, Heroku, ZeroThreat, Invicti API Security, 42Crunch, Data Theorem, and Cequence API Sentinel.

scanR, le moteur de la recherche et de l'innovation recense plus de 90 000 financements de projets (ANR, FP7, H2020, PHC, PHRC, Casdar, thèses Ademe, PIA, INCA, Innovation 2030, REACTING). Les données présentées ne sont pas exhaustives. En effet, en contradiction avec les termes de la loi n° 2016-1321 of 7 octobre 2016 Pour une République numérique, toutes les données sur les financements publics de la recherche sur appel à projet ne sont pas accessibles. scanR valorise et intègre toutes les données auxquelles il accède. Dans certains cas, l'information est accessible via des bases de données ou des API mises à disposition par le producteur de la donnée. Dans d'autres cas, scanR ne dispose que de l'information diffusée de manière ouverte sur le site web de l'institution en charge du financement. Si les résultats d'une agence de financement n'y figure pas c'est que scanR n'accède pas à ces données ou que, compte tenu de la qualité de l'information disponible, le coût de traitement de l'information accessible est trop élevé. L'ensemble des données à date (dump) sont disponibles en téléchargement à cette adresse : https://scanr-data.s3.gra.io.cloud.ovh.net/production/projects_denormalized.jsonl.gz Ces données sont également accessibles via l'api de scanR.

scanR, le moteur de la recherche et de l'innovation recense plus de 42 000 entités publiques ou privées françaises. scanR couvre l'ensemble des structures de recherche référencées dans le Répertoire national des structures de recherche (RNSR) ainsi que leur tutelle. Il couvre également, de la manière la plus complète possible, l'ensemble des institutions publiques ou privées, avec ou sans but lucratif mentionnées dans les principales sources mobilisées. L'ensemble des données à date (dump) sont disponibles en téléchargement à cette adresse : Ces données sont également accessibles via l'api de scanR

Scan Designs Limited Company Export Import Records. Follow the Eximpedia platform for HS code, importer-exporter records, and customs shipment details.

scanR identifierar forsknings- och innovationsmotorn mer än 90000 projektfinansiering (ANR, FP7, H2020, PHC, PHRC, Casdar, avhandlingarna Ademe, PIA, INCA, Innovation 2030, Reacting).

De uppgifter som presenteras är inte uttömmande. I motsats till vad som anges i lag nr 2016–1321 av den 7 oktober 2016 För en digital republik är alla uppgifter om offentlig finansiering av forskning i ansökningsomgångar inte tillgängliga. scanR-värden och integrerar alla uppgifter som den har tillgång till. I vissa fall är informationen tillgänglig via databaser eller API:er som görs tillgängliga av dataproducenten. I andra fall har ScanR endast information som sprids på ett öppet sätt på webbplatsen för den institution som ansvarar för finansieringen. Om resultaten från ett finansieringsorgan inte ingår får ScanR inte tillgång till uppgifterna eller, med tanke på kvaliteten på den tillgängliga informationen, är kostnaden för att behandla den tillgängliga informationen för hög.

Alla data hittills (dump) finns tillgängliga för nedladdning på denna adress:

’HTTPS://STORAGE.GRA.CLOUD.OVH.NET/V1/AUTH_32C5D10CB0FE4519B957064A111717E3/SCANR/PROJECTS.JSON’

Dessa uppgifter är också tillgängliga via api de scanR.

This dataset provides locations and related information for WISEWOMAN SCAN - All as of 04/24/2017 based on information provided by the ISDH Chronic Disease Program. All screening services available through the Well-Integrated Screening and Evaluation for Women Across the Nation (WISEWOMAN) SCAN. Visit http://www.in.gov/isdh/26543.htm for more information about this resource.

ScanR, il-magna tar-riċerka u l-innovazzjoni tidentifika aktar minn 90000 finanzjament tal-proġett (ANR, FP7, H2020, PHC, PHRC, Casdar, theses Ademe, PIA, INCA, Innovation 2030, REACTing).

Id-data ppreżentata mhijiex eżawrjenti. Fil-fatt, kuntrarjament għat-termini tal-Liġi Nru 2016–1321 tas-7 ta’ Ottubru 2016 Għal Repubblika Diġitali, id-data kollha dwar il-finanzjament pubbliku ta’ riċerka fuq sejħa għal proġetti mhijiex aċċessibbli. F’xi każijiet, l-informazzjoni tkun aċċessibbli permezz ta’ bażijiet tad-data jew APIs magħmula disponibbli mill-produttur tad-data. F’każijiet oħra, l-iskennjar għandu biss informazzjoni mxerrda b’mod miftuħ fuq is-sit web tal-istituzzjoni inkarigata mill-finanzjament. Jekk ir-riżultati ta’ aġenzija ta’ finanzjament ma jkunux inklużi, l-iscanR ma jaċċessax id-data jew, minħabba l-kwalità tal-informazzjoni disponibbli, l-ispiża tal-ipproċessar tal-informazzjoni aċċessibbli tkun għolja wisq. Id-data kollha sal-lum (dump) hija disponibbli biex titniżżel f’dan l-indirizz:

“HTTPS://STORAGE.GRA.CLOUD.OVH.NET/V1/AUTH_32C5D10CB0FE4519B957064A111717E3/SCANR/PROJECTS.JSON”

Din id-data hija aċċessibbli wkoll permezz tal-api de scanR.

The global metrology 3D scanner market is experiencing robust growth, driven by increasing adoption across diverse industries. The market, estimated at $2 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 15% from 2025 to 2033, reaching an estimated market value of $6.2 billion by 2033. This expansion is fueled by several key factors: the rising demand for precise dimensional measurements in manufacturing processes, particularly in automotive, aerospace, and healthcare; the increasing adoption of automation and digitalization in quality control procedures; and the growing need for efficient reverse engineering solutions. Furthermore, advancements in 3D scanning technology, leading to improved accuracy, speed, and ease of use, are contributing significantly to market growth. The market is segmented by application (reverse engineering, quality control, and other) and type (desktop and portable), with portable scanners gaining traction due to their flexibility and portability. Key players such as AMETEK (Creaform), Carl Zeiss, Nikon Metrology, Polyga, API Metrology, Shining 3D, Scantech, and Artec 3D are actively shaping market dynamics through continuous innovation and expansion into new geographic regions. While the North American and European markets currently hold significant shares, the Asia-Pacific region is expected to witness substantial growth in the coming years, driven by expanding manufacturing industries in countries like China and India. However, market growth may face challenges such as the high initial investment cost associated with 3D scanners and the need for skilled operators. Despite these restraints, the overall market outlook remains positive, fueled by technological advancements and the continuous demand for precise measurements across various sectors. This report provides a detailed analysis of the global Metrology 3D scanner market, projecting a market value exceeding $2.5 billion by 2028. We delve into key market trends, growth drivers, and challenges, offering valuable insights for stakeholders across the manufacturing, automotive, aerospace, and healthcare industries. The report utilizes rigorous data analysis and expert insights to forecast market dynamics and identify lucrative investment opportunities.

Scan Pot Aps Company Export Import Records. Follow the Eximpedia platform for HS code, importer-exporter records, and customs shipment details.

Eximpedia Export import trade data lets you search trade data and active Exporters, Importers, Buyers, Suppliers, manufacturers exporters from over 209 countries

This dataset provides locations and related information for WISEWOMAN SCAN - Housing as of 04/24/2017 based on information provided by the ISDH Chronic Disease Program. Housing available through the Well-Integrated Screening and Evaluation for Women Across the Nation (WISEWOMAN) program. Visit http://www.in.gov/isdh/26543.htm for more information about this resource.

The global handheld metrology-grade 3D scanner market is experiencing robust growth, driven by increasing adoption across diverse sectors. The market, valued at approximately $2 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 15% from 2025 to 2033. This expansion is fueled by several key factors. Firstly, advancements in sensor technology, particularly in laser and structured light scanning, are leading to improved accuracy, speed, and portability of these scanners. This enables efficient data capture in various challenging environments, including on-site inspections and reverse engineering applications. Secondly, the rising demand for quality control and assurance across industries like automotive, aerospace, and consumer goods is significantly boosting the market. Manufacturers increasingly rely on precise 3D scanning for product inspection, ensuring dimensional accuracy and minimizing defects. Finally, the growing adoption of digital twin technology is creating new opportunities for handheld 3D scanners in product development and maintenance processes. The market is segmented by application (reverse engineering, quality control, and others) and scanner type (laser and structured light), with laser scanners currently holding a larger market share due to their superior precision for complex geometries. Leading players like AMETEK (Creaform), Carl Zeiss, Nikon Metrology, and Shining 3D are constantly innovating and expanding their product portfolios to cater to this growing demand. While the market presents significant opportunities, certain restraints exist. The relatively high cost of advanced handheld 3D scanners can limit adoption among small and medium-sized enterprises. Furthermore, the need for specialized expertise to operate and interpret the data generated by these scanners can pose a challenge. However, ongoing technological advancements are addressing these issues through user-friendly software and reduced system costs. The market is geographically diverse, with North America and Europe currently leading in adoption, but regions like Asia-Pacific are witnessing rapid growth due to increasing industrialization and investment in advanced manufacturing technologies. The forecast period (2025-2033) anticipates continued market expansion, driven by persistent technological innovation and increasing demand for precise dimensional measurement across diverse applications.

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The Ioversol API market is experiencing steady growth, projected to reach a market size of $182.1 million in 2025, with a compound annual growth rate (CAGR) of 4.2% from 2025 to 2033. This growth is fueled by several key factors. Increasing demand for advanced medical imaging techniques, particularly in developing economies, is a significant driver. Technological advancements in API design and functionality are leading to improved diagnostic accuracy and efficiency. Furthermore, the rising prevalence of diseases requiring advanced imaging, coupled with a growing elderly population, contributes significantly to market expansion. The market is seeing increasing adoption in various applications such as Computed Tomography (CT) and Magnetic Resonance Imaging (MRI) scans. Leading companies like Guerbet Group, Brother Technology, and Stellite are actively involved in the development and distribution of Ioversol API, driving competition and innovation within the sector. The market is segmented based on factors like application, end-user, and geographic region. While precise regional data is unavailable, it is reasonable to assume a distribution mirroring global healthcare trends, with North America and Europe holding the largest market shares. The competitive landscape is characterized by both established players and emerging companies vying for market share, which fuels further innovation and contributes to the overall market growth. The forecast period of 2025-2033 anticipates continued market expansion, driven by factors such as ongoing technological advancements in medical imaging, increasing government investments in healthcare infrastructure, and favorable regulatory environments in various regions. Challenges such as stringent regulatory approvals for new APIs and the potential for substitutes pose some restraints to the market's growth. However, the long-term outlook remains positive, with significant growth potential projected across various segments and geographies. Strategic partnerships, mergers, and acquisitions are expected to further shape the competitive dynamics within this expanding market.

Terrestrial laser scanning data of the slopes above the A83 Rest and Be Thankful collected by a Riegl LMS Z620i instrument in 2016 after Storms Desmond and Frank from 3 positions. These data are scanner centric coordinates which the end-user needs to align and (if required) align into a global coordinate system. Data are in raw format, supplied as .las with scaled intensity included.

scanR, le moteur de la recherche et de l'innovation recense plus de 4 millions de productions scientifiques françaises : - les publications scientifiques depuis 2013 sont identifiées via https://unpaywall.org/ et complétées par HAL proposé par le Centre pour la Communication Scientifique Directe (CCSD) du Centre national de la recherche scientifique- Les thèses sont identifiées via http://theses.fr/ de l'Agence bibliographique de l'enseignement supérieur (Abes) et complétées par https://tel.archives-ouvertes.fr/ proposé par le CCSD- une extraction du Système universitaire de documentation (Sudoc) de l'Abes permet d'identifier une partie des ouvrages et monographies publiés depuis 2013- la base Patstat de l'Office européen des brevets (OEB) permet d'identifier les familles de brevets publiés depuis 2010 comprenant des déposants et/ou inventeurs associés au territoire national.

L'ensemble des données à date (dump) sont disponibles en téléchargement à cette adresse : https://scanr-data.s3.gra.io.cloud.ovh.net/production/publications_denormalized.jsonl.gz

Ces données sont également accessibles via l'api de scanR

Coral specimens collected in the St. Thomas, U.S. Virgin Islands and Belize were 3-dimensionally scanned. This dataset includes metadata on the coral samples such as the collection location and conditions, and the dimensions of the samples. The STL files are available for download in the Supplemental Documentation section below. access_formats=.htmlTable,.csv,.json,.mat,.nc,.tsv,.esriCsv,.geoJson,.odvTxt acquisition_description=Caribbean acroporids (Acropora palmata, A. cervicornis, and A. prolifera) corals were photographed, measured, and collected and transported in coolers of seawater to the laboratory for 3D scans. Corals were kept in a seawater system or under the laboratory dock until scanning commenced.\u00a0 Corals were first photographed, then landmarks (i.e., small balls of modeling clay) were added to the corals to assist with alignments during post-scan analyses, and the coral was scanned.

3D scans of corals were edited in Scan Studio software. Any unnecessary part of the scan was trimmed off, such as the stand that corals were propped on. Multiple scans were aligned using strategically placed markers that were placed on the corals prior to scanning. After aligning the scans, markers were trimmed off, and the image was fused in order to fill any existing holes.

Once .stl files were exported from the scanner software, files were uploaded to Autodesk Meshmixer (Ver. 3.4.35). While in the Meshmixer software, most files had the mesh repaired and filled in using the \u201cmake solid\u201d tool in the \u201cedit\u201d tab. In the \u201cMake Solid tool \u201cSharp Edge Preserve\u201d is to be selected for the \u201cSolid Type\u201d while \u201cSolid Accuracy\u201d is set to 500, and \u201cMesh Density\u201d is set to 420, all other settings remained the standard. However, prior to making it solid the \u201cSculpt\u201d tool was used for the dense branched A. prolifera. The \u201cInflate\u201d brush was used at various strength and sizes to build in sections of branches what were not completely formed during scanning. awards_0_award_nid=663802 awards_0_award_number=OCE-1538469 awards_0_data_url=https://www.nsf.gov/awardsearch/showAward?AWD_ID=1538469 awards_0_funder_name=NSF Division of Ocean Sciences awards_0_funding_acronym=NSF OCE awards_0_funding_source_nid=355 awards_0_program_manager=Michael E. Sieracki awards_0_program_manager_nid=50446 cdm_data_type=Other comment=Caribbean acroporids 3D scans and specimen metadata PI: N. Fogarty (Nova U) version: 2019-01-09 Conventions=COARDS, CF-1.6, ACDD-1.3 data_source=extract_data_as_tsv version 2.3 19 Dec 2019 defaultDataQuery=&time<now doi=10.1575/1912/bco-dmo.752642.1 Easternmost_Easting=-64.902765 geospatial_lat_max=18.404256 geospatial_lat_min=16.917861 geospatial_lat_units=degrees_north geospatial_lon_max=-64.902765 geospatial_lon_min=-87.768908 geospatial_lon_units=degrees_east infoUrl=https://www.bco-dmo.org/dataset/752642 institution=BCO-DMO instruments_0_dataset_instrument_nid=752672 instruments_0_description=A 3D scan captures digital information about the shape of an object with equipment that uses a laser or light to measure the distance between the scanner and the object. instruments_0_instrument_name=3D scanner instruments_0_instrument_nid=752673 instruments_0_supplied_name=Next Engine Ultra HD 3D Scanner metadata_source=https://www.bco-dmo.org/api/dataset/752642 Northernmost_Northing=18.404256 param_mapping={'752642': {'Collection_Depth_ft': 'master - depth', 'latitude': 'master - latitude', 'Scan_Date': 'flag - time', 'longitude': 'master - longitude'}} parameter_source=https://www.bco-dmo.org/mapserver/dataset/752642/parameters people_0_affiliation=Nova Southeastern University people_0_person_name=Nicole Fogarty people_0_person_nid=663800 people_0_role=Principal Investigator people_0_role_type=originator people_1_affiliation=Woods Hole Oceanographic Institution people_1_affiliation_acronym=WHOI BCO-DMO people_1_person_name=Nancy Copley people_1_person_nid=50396 people_1_role=BCO-DMO Data Manager people_1_role_type=related project=Coral Hybridization projects_0_acronym=Coral Hybridization projects_0_description=NSF Award Abstract: Reef-building acroporid corals form the foundation of shallow tropical coral communities throughout the Caribbean. Yet, the once dominant staghorn coral (Acropora cervicornis) and the elkhorn coral (A. palmata) have decreased by more than 90% since the 1980s, primarily from disease. Their continuing decline jeopardizes the ability of coral reefs to provide numerous societal and ecological benefits, including economic revenue from seafood harvesting and tourism and shoreline protection from extreme wave events caused by storms and hurricanes. Despite their protection under the U.S. Endangered Species Act since 2006, threats to the survival of reef-building acroporid corals remain pervasive and include disease and warming ocean temperatures that may lead to further large-scale mortality. However, hybridization among these closely related species is increasing and may provide an avenue for adaptation to a changing environment. While hybrids were rare in the past, they are now thriving in shallow habitats with extreme temperatures and irradiance and are expanding into the parental species habitats. Additional evidence suggests that the hybrid is more disease resistant than at least one of the parental species. Hybridization may therefore have the potential to rescue the threatened parental species from extinction through the transfer of adapted genes via hybrids mating with both parental species, but extensive gene flow may alter the evolutionary trajectory of the parental species and drive one or both to extinction. This collaborative project is to collect genetic and ecological data in order to understand the mechanisms underlying increasing hybrid abundance. The knowledge gained from this research will help facilitate more strategic management of coral populations under current and emerging threats to their survival. This project includes integrated research and educational opportunities for high school, undergraduate and graduate students, and a postdoctoral researcher. Students in the United States Virgin Islands will take part in coral spawning research and resource managers will receive training on acroporid reproduction to apply to coral restoration techniques. Current models predict the demise of reefs in the next 200 years due to increasing sea surface temperatures and ocean acidification. It is thus essential to identify habitats, taxa and evolutionary mechanisms that will allow some coral species to maintain their role as foundation fauna. Hybridization can provide an avenue for adaptation to changing conditions. Corals hybridize with some frequency and results may range from the introduction of a few alleles into existing parent species via introgression, to the birth of a new, perhaps better adapted genetic lineage. The only widely accepted coral hybrid system consists of the once dominant but now threatened Caribbean species, Acropora cervicornis and A. palmata. In the past, hybrid colonies originating from natural crosses between elkhorn and staghorn corals were rare, and evidence of hybrid reproduction was limited to infrequent matings with the staghorn coral. Recent field observations suggest that the hybrid is increasing and its ecological role is changing throughout the Caribbean. These hybrids appear to be less affected by the disease that led to the mass mortality of their parental species in recent decades. Hybrids are also found thriving in shallow habitats with high temperatures and irradiance suggesting they may be less susceptible to future warming scenarios. At the same time, they are expanding into the deeper parental species habitats. Preliminary genetic data indicate that hybrids are now mating with each other, demonstrating the potential for the formation of a new species. Further, hybrids appear to be capable of mating with both staghorn and elkhorn coral, perhaps leading to gene flow between the parent species via the hybrid. Research is proposed to address how the increase in hybridization and perhaps subsequent introgression will affect the current ecological role and the future evolutionary trajectory of Caribbean acroporids. Specifically, this collaborative project aims to answer the following questions: 1) What is the historic rate, direction, and degree of introgression across species ranges and genomes? Linkage block analysis based on genome-wide SNP genotyping across three replicate hybrid zones will answer this question. 2) What is the current extent and future potential of later generation hybrid formation? Morphometric and genetic analyses combined with in vitro fertilization assays will be used. 3) What mechanisms allow hybrids to thrive in hot, shallow waters? A series of manipulative in situ and ex situ experiments will determine whether biotic or abiotic factors favor hybrid survival in shallow waters. 4) Are hybrids more disease resistant than the parentals species? Disease transmission assays in reciprocal transplant experiments and histological analysis to determine the extent of disease will be conducted. A multidisciplinary approach will be taken that combines traditional and cutting edge technology to provide a detailed analysis of the evolutionary ecology of Caribbean corals. Note: PI Nicole Fogarty's original award OCE-1538469 was issued while at Nova Southeastern University. This was replaced by OCE-1929979 upon moving to the University of North Carolina Wilmington. projects_0_end_date=2020-09 projects_0_geolocation=Caribbean and North-West Atlantic projects_0_name=Collaborative research: Is hybridization among threatened Caribbean coral species the key to their survival or the harbinger of their extinction? projects_0_project_nid=663794 projects_0_start_date=2015-10 sourceUrl=(local files) Southernmost_Northing=16.917861 standard_name_vocabulary=CF

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