Principles of drawing up and possibilities of using tactile maps in teaching geography

AbstractIn this study, we compared cognitive map formation of small-scale models of city-like environments presented in visual or tactile/haptic modalities. Previous research often addresses only a limited amount of cognitive map aspects. We wanted to combine several of these aspects to elucidate a more complete view. Therefore, we assessed different types of spatial information, and consider egocentric as well as allocentric perspectives. Furthermore, we compared haptic map learning with visual map learning. In total 18 sighted participants (9 in a haptic condition, 9 visuo-haptic) learned three tactile maps of city-like environments. The maps differed in complexity, and had five marked locations associated with unique items. Participants estimated distances between item pairs, rebuilt the map, recalled locations, and navigated two routes, after learning each map. All participants overall performed well on the spatial tasks. Interestingly, only on the complex maps, participants performed worse in the haptic condition than the visuo-haptic, suggesting no distinct advantage of vision on the simple map. These results support ideas of modality-independent representations of space. Although it is less clear on the more complex maps, our findings indicate that participants using only haptic or a combination of haptic and visual information both form a quite accurate cognitive map of a simple tactile city-like map.

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Cognitive Mapping by the Blind

Journal of Visual Impairment & Blindness ◽

10.1177/0145482x7807200801 ◽

1978 ◽

Vol 72 (8) ◽

pp. 297-301 ◽

Cited By ~ 1

Author(s):

Steven M. Casey

Keyword(s):

High School ◽

High School Students ◽

Cognitive Mapping ◽

School Students ◽

Congenitally Blind ◽

Tactile Maps ◽

Blind Persons ◽

Partially Sighted ◽

Blind Students

In an effort to study the cognitive mapping abilities of blind persons, tactile maps of a school campus were made by ten congenitally blind and ten blindfolded partially sighted high school students. Although some blind students made well-organized and accurate maps of the campus, most of the maps made by the congenitally blind subjects were poorly organized and integrated as compared with maps made by the blindfolded partially sighted subjects. Blind persons exhibit varying methods for categorizing the elements of a large environment, and the method of cognitive mapping is believed to be related to how well a person can negotiate within the environment.

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Toward Accessible Hazard Mapping: Tactile Risk Maps and Disaster Preparedness

Abstracts of the ICA ◽

10.5194/ica-abs-1-47-2019 ◽

2019 ◽

Vol 1 ◽

pp. 1-1

Author(s):

Harrison Cole

Keyword(s):

Emergency Management ◽

Visual Impairment ◽

Natural Hazards ◽

Disaster Preparedness ◽

Spatial Information ◽

Visual Impairments ◽

Hazard Mapping ◽

Risk Maps ◽

Risk Visualization ◽

Tactile Maps

Abstract. The near future of our planet under climate change is predicted to be characterized by increasingly frequent and severe natural hazards of all kinds. Understanding the potential spatial extent and impacts of these hazards is a critical component of creating effective emergency management plans, not just on the part of emergency managers and relief organizations, but also for those who may reside in areas vulnerable to disaster. Often, information about disaster risk is communicated using maps, such as in the case of storm surge maps, evacuation zone maps or wildfire extent maps. While generally helpful, these maps are of limited use to those with low vision or blindness, and the information is rarely, if ever, distributed in accessible formats. Furthermore, in contrast to wayfinding maps, this type of information does not lend itself to being translated into a set of instructions to be read aloud by a test-to-speech device. Instead, risk maps are useful because they allow users to identify and assess spatial relationships between many features on the maps- a key process that would be muddled if the maps were to be verbally described, and thus a process that is currently inaccessible to those who cannot see the maps. As people with visual impairments are especially vulnerable in disaster scenarios, working towards the universal accessibility of spatial information is imperative for inclusive disaster preparedness and hazard mitigation.Many challenges exist in creating maps for people with visual impairments. The most obvious is the fact that a visual medium cannot be used by someone who is unable to see. It is important to note that “visual impairment” covers a broad spectrum of conditions from pronounced myopia to complete blindness. Here, I will be limiting my topical scope to people with total or near-total blindness. Tactile maps are the tool of choice for this population. However, it is generally harder to distinguish between similar patterns using touch than using sight, so features on a tactile map need to be unique and unambiguous. This makes it more challenging to communicate information typically represented using color gradients or transparency. Additionally, distributing spatial information in tactile form poses another layer of complications. There are several options for creating tactile maps, from embossed paper to 3D printing, and each come with their own advantages and drawbacks. Cost, speed and detail all vary among these media, and thus each potentially impact the user’s perception of risk. In my talk, I will be examining these challenges as they intersect with research on cartographic risk visualization, emergency management, and tactile maps in general. First, I will briefly discuss the state of risk visualization in the context of emergency management, focusing on preparedness. Then, I will give a general overview of the extant research on tactile maps with particular attention paid to their influence on spatial cognition. Next, I will examine how the considerations particular to risk map creation are affected by the potentials and limitations of tactile maps. Finally, I will outline a research agenda for creating and distributing accessible maps for emergency management. Using visual impairment and tactile maps as starting points, I will identify further aspects of emergency management that urgently require greater attention to accessibility, and how cartographic research and technology can help bridge those gaps. Planning for natural hazards is an essential step in mitigating their impacts on communities, and that process includes individual citizens making their own plans for evacuation, finding shelter or securing food, water or medicine. This is especially important for people with disabilities, as resources deployed after a disaster may fail to accommodate their particular needs, and processes such as evacuating a building or house can take substantially longer than average. Planning for these scenarios is made all the more difficult for people with visual impairments, as conventional maps are unhelpful, and environmental awareness is limited. Thus, empowering people with visual impairments to make emergency plans for themselves and contribute to planning for their community as a whole can help build autonomy and self-confidence and ultimately ensure that disaster plans truly account for everyone.

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TouchIt3D: Technology (not only) for Tactile Maps

Abstracts of the ICA ◽

10.5194/ica-abs-1-24-2019 ◽

2019 ◽

Vol 1 ◽

pp. 1-2

Author(s):

Radek Barvir ◽

Alena Vondrakova ◽

Jan Brus

Keyword(s):

Visual Impairment ◽

Mobile Devices ◽

Visually Impaired ◽

Spatial Context ◽

User Needs ◽

The Real ◽

Visually Impaired People ◽

Impaired People ◽

Map Symbol ◽

Tactile Maps

Abstract. The majority of information has a spatial context that can be represented on the map, while maps are presenting the real world in the simplified and generalised way, focusing on the key features or specific topic. For some kinds of users, the map as the representation of the real spatial context is not only the possibility but also the necessity. Among these people belong people with visual impairments. The number of visually impaired people increases every year and to their full-fledged integration into society is devoted considerable attention. But People with visual impairments are the target group with specific user needs, and the conventional map is insufficient for them. Along the growing number of visually impaired people importance of tactile cartography is increasing. Currently, there are many technologies used for creating tactile maps, including very primitive and cheap solutions as well as advanced methods. The simplest way is drawing on the hand which brings only the real-time perception which needs to memorise for next uses. Another technique of hand embroidery consists of thick fibre placed on the cardboard or different paper type. More accurate is drawing on a special paper for blind or using dense colour gels. Also, some kinds of machinery producing technologies are used, e.g: shaping carton, plastic or metal. Braille printers can produce not very complicated tactile maps using 3D dots. Similar results can be obtained using serigraphy. Very popular is printing on heat-sensitive paper as mentioned before in the case of haptic maps by Mapy.cz. Another possibility is to use rubberized colours and nowadays popular technology of 3D printing (Vozenilek and Ludikova, 2010). At the Department of Geoinformatics, Faculty of Science, Palacký University Olomouc, Czechia, the research team developed prototypes and methodology for the creation of the modern type of 3D tactile maps, linkable with mobile devices (Barvir et al., 2018).Interactive tactile maps connectable with mobile devices bring new opportunities to develop tactile map production. The prototypes have been verified in practice in cooperation with educational centres for people with visual impairment and blind people, and special schools. It is comprehensive research focusing a lot of scientific challenges. The contribution would like to summarise the most significant findings of the research. The developed TouchIt3D technology is based on linking 3D objects, such as tactile maps, 3D models, controls, etc., with a mobile tablet or mobile phone using a combination of conductive and non-conductive filament. Each model is linked to an individual mobile application layout that initiates a pre-action based on user suggestions done within touching the model. For example, such an action may be a vibration or a speech command when the person with visual impairment touch inappropriate map symbol. As example can be introduced a listing of current public transport departures after the user touches the bus-stop map symbol on the 3D transport terminal plan. Data can be acquired in real time via Internet as the tablet can be connected to WiFi or cellular network. TouchIt3D technology is primarily focused on the presentation of spatial data and navigation for the public, people with visual or other impairment. There are two ways how to create such tactile map. The first way is to prepare all the data manually. Another approach is the semi-automatic workflow. This approach is significantly different from previous workflows of producing maps for people with visual impairment. The solution based on the open-source and free software and data together with sharing electronic part of the map in the form of tablet dramatically lowered costs of tactile maps production. The designed scripts and models also reduced the time necessary to spend by map designing up to a minimum. User testing provided all data required for the improvement, and maximal adaptation of the cartographic visualisation methods to the target user needs. Nevertheless, maps partly automatically done and based on crowdsourcing data cannot bring the same quality as individually made tactile maps. The main aim of the research is to find a workflow of interactive tactile maps creation using the TouchIt3D technology. The research also deals with setting appropriate parameters of the map, e.g. the map scale, cartographic symbol size, map content etc. This optimisation is done to fit the needs of people with visual impairment as much as possible on the one hand and taking into account the limitations of the map creation possibilities.This research is implemented within the project Development of independent movement through tactile-auditory aids, Nr. TL01000507, supported by the Technology Agency of the Czech Republic.

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INFERRING THE SCALE AND CONTENT OF A MAP USING DEEP LEARNING

ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences ◽

10.5194/isprs-archives-xliii-b4-2020-17-2020 ◽

2020 ◽

Vol XLIII-B4-2020 ◽

pp. 17-24

Author(s):

G. Touya ◽

F. Brisebard ◽

F. Quinton ◽

A. Courtial

Keyword(s):

Neural Networks ◽

Deep Learning ◽

Convolutional Neural Networks ◽

Visually Impaired ◽

The Other ◽

Visually Impaired People ◽

Impaired People ◽

Tactile Maps

Abstract. Visually impaired people cannot use classical maps but can learn to use tactile relief maps. These tactile maps are crucial at school to learn geography and history as well as the other students. They are produced manually by professional transcriptors in a very long and costly process. A platform able to generate tactile maps from maps scanned from geography textbooks could be extremely useful to these transcriptors, to fasten their production. As a first step towards such a platform, this paper proposes a method to infer the scale and the content of the map from its image. We used convolutional neural networks trained with a few hundred maps from French geography textbooks, and the results show promising results to infer labels about the content of the map (e.g. ”there are roads, cities and administrative boundaries”), and to infer the extent of the map (e.g. a map of France or of Europe).

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