Hampshire County, Massachusetts, 1856 (Raster Image)

This layer is a georeferenced raster image of the historic paper map entitled: A topographical map of Hampshire County, Massachusetts, the details from actual surveys under the direction of H.F. Walling, superintendent of the state map. It was published by Sarony & Co. in 1856. Scale [ca. 1:48,500]. The image inside the map neatline is georeferenced to the surface of the earth and fit to the Massachusetts State Plane Coordinate System, Mainland Zone (in Feet) (Fipszone 2001). All map collar and inset information is also available as part of the raster image, including any inset maps, profiles, statistical tables, directories, text, illustrations, or other information associated with the principal map. This map shows features such as roads, railroads, drainage, public buildings, schools, churches, cemeteries, industry locations (e.g. mills, factories, mines, etc.), private buildings with names of property owners, town and county boundaries and more. Relief is shown by hachures. It includes many cadastral insets of individual county towns and villages, and an inset geological map of county. This map represents county boundaries as of 1856, thus portions of the towns of Holyoke (Hampden County), New Salem (Franklin County), and Petersham (Worcester County) are also represented on this map. This layer is part of a selection of digitally scanned and georeferenced historic maps of Massachusetts from the Harvard Map Collection. These maps typically portray both natural and manmade features. The selection represents a range of regions, originators, ground condition dates (1755-1922), scales, and purposes. The digitized selection includes maps of: the state, Massachusetts counties, town surveys, coastal features, real property, parks, cemeteries, railroads, roads, public works projects, etc.

Aplicações baseadas em geolocalizações para gestão de instalações desportivas: exemplo de utilização da API da GOOGLE Maps no concelho de Guimarães

O contexto tecnológico em que vivemos é uma realidade. E a tendência é para ser assim também no futuro. Cada vez mais. É o caso das representações de locais e entidades em mapas digitais na web. Na visão de Crocker (2014), esta tendência é ainda mais acentuada, no âmbito das aplicações móveis, como mostram as mais diversas location-based applications. No setor do desporto e da respetiva gestão nem sempre foi fácil desenvolver aplicações, recorrendo a este tipo de representações espaciais. A tecnologia não era fácil e o know-how não era adequadamente qualificado. Mas, as empresas fornecedoras de tecnologia geoespacial simplificaram o desenvolvimento de aplicações web nesta área, através da utilização de application programming interfaces (API). Como refere Svennerberg (2010), estas API’s servem de interface entre um serviço proporcionado por uma empresa, caso da Google Maps (2013) e uma aplicação web ou móvel que utiliza esses serviços. Foi com este objetivo que desenvolvemos uma aplicação web, utilizando as metodologias próprias neste domínio, como a framework de Zachman (2009), tal como foi originalmente adaptada por Whitten e Bentley (2005), onde um dos módulos é precisamente a representação de espaços desportivos, recorrendo à utilização dos serviços da Google Maps. Para além disso, toda a aplicação é suportada numa abordagem Model-View-Control (MVC). Para conseguir representar as instalações desportivas num mapa, criámos uma base de dados MySQL, com dados de longitude e latitude, de cada instalação desportiva. Através de JavaScript criou-se o mapa propriamente dito, indicando o tipo (mapa de estradas, satélite ou street view) e as respetivas opções (nível de zoom, alinhamento, controlo de interface e posicionamente, entre muitas outras opções). O passo seguinte consistiu em passar os dados para o frontend da aplicação web. Para isso, recorreu-se à integração do PHP com as livrarias externas de código JavaSrcipt, criadas especificamente para o efeito (caso da MarkerManager). A implementação destas funcionalidades permite georeferenciar todos os tipos e géneros de espaços desportivos de um concelho, região ou País. Obteve-se ainda know-how, background e massa crítica, para o desenvolvimento de novas funcionalidades. A sua utilização em dispositivos móveis é outra das possibilidades atualmente já em desenvolvimento.

City of Ann Arbor, Washtenaw County, Michigan

Map shows size city wards, township sections, lot boundaries, buildings and other cultural features, and sections of land annexed by the city.

Water resources of Teton County, Wyoming, exclusive of Yellowstone National Park /

Three maps on 3 folded leaves in pocket.

Erie; a guide to the city and county,

"First edition."

Physical land conditions in Clarke county, Georgia,

In pamphlet box with 19 additional folded maps.

A report on the general soil areas and slope classes in small watersheds, Broome County, New York / by Carl S. Pearson.

Two folded maps in pocket.

Soil survey of McLeod County, Minnesota /

"Index to map units"--P. v, pt. 1.

A topographical and historical description of the county of York; containing an account of its towns, cathedral, castles, antiquities, churches, monuments, public edifices, picturesque scenery, the residences of the nobility, gentry, &c. accompanied with biographical notices of eminent and learned men to whom this county has given birth.

A separate issue, with new t.-p., of a part of v. 16 of The beauties of England and Wales.

Map showing where Sandia points were found in Cass County

Caption: Map from the Directory of Cass County 1953-1954 Compiled by Floyd Wagner, County Clerk of Cass County [blue dot] for each find

Composite of 1909 Huron River maps by Gardner S. Wiliams.

(Composite created from Bentley Historical Library scans of maps from the Gardner S. Williams collection. Image created by Huron River Watershed Council staff.)

The bibliographer's manual of Gloucestershire literature ; being a classified catalogue of books, pamphlets, broadsides, and other printed matter relating to the county of Gloucester or to the city of Bristol, with descriptive and explanatory notes.

Bookplate of Henley Evans, Clifton.

1920 assessments : Unit value maps of Cleveland, East Cleveland, Lakewood & Cleveland Heights,

Title from cover.

The history and topographical survey of the county of Kent. Containing the antient and present state of it, civil and ecclesiastical;

Vol. 13 is a made-up volume containing maps and folded plans.

Development of an odor management plan for industrial stationary sources in an urban environment: A case study for Broward County, Florida

Objectionable odors remain at the top of air pollution complaints in urban areas such as Broward County that is subject to increasing residential and industrial developments. The odor complaints in Broward County escalated by 150 percent for the 2001 to 2004 period although the population increased by only 6 percent. It is estimated that in 2010 the population will increase to 2.5 million. Relying solely on enforcing the local odor ordinance is evidently not sufficient to manage the escalating odor complaint trends. An alternate approach similar to odor management plans (OMPs) that are successful in managing major malodor sources such as animal farms is required. ^ This study aims to develop and determine the feasibility of implementing a comprehensive odor management plan (COMP) for the entire Broward County. Unlike existing OMPs for single sources where the receptors (i.e. the complainants) are located beyond the boundary of the source, the COMP addresses a complex model of multiple sources and receptors coexisting within the boundary of the entire county. Each receptor is potentially subjected to malodor emissions from multiple sources within the county. Also, the quantity and quality of the source/receptor variables are continuously changing. ^ The results of this study show that it is feasible to develop a COMP that adopts a systematic procedure to: (1) Generate maps of existing odor complaint areas and malodor sources, (2) Identify potential odor sources (target sources) responsible for existing odor complaints, (3) Identify possible odor control strategies for target sources, (4) Determine the criteria for implementing odor control strategies, (5) Develop an odor complaint response protocol, and (6) Conduct odor impact analyses for new sources to prevent future odor related issues. Geographic Information System (GIS) is used to identify existing complaint areas. A COMP software that incorporates existing United States Environmental Protection Agency (EPA) air dispersion software is developed to determine the target sources, predict the likelihood of new complaints, and conduct odor impact analysis. The odor response protocol requires pre-planning field investigations and conducting surveys to optimize the local agency available resources while protecting the citizen's welfare, as required by the Clean Air Act. ^