Geographic Information System (GIS)
Mina Karimi; Mohammad Saedi Mesgari
Abstract
Extended Abstract1. IntroductionIn GIScience, spatial information has usually been presented in the form of space. However, human reasoning, behavior, and perception are mainly based on place, not space. Places are usually ambiguous and context-dependent and are related to the human experience of the ...
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Extended Abstract1. IntroductionIn GIScience, spatial information has usually been presented in the form of space. However, human reasoning, behavior, and perception are mainly based on place, not space. Places are usually ambiguous and context-dependent and are related to the human experience of the world. Place functionality as a context in place descriptions is one of the main and distinguishing features of the place. Today, with the increasing use of users of social networks, volunteered geographic information (VGI) and crowdsourcing information has grown significantly. However, information obtained from social networks, e.g. check-ins, often does not have a complete and clear view of the concept of place and it does not include spatial information between phenomena, land uses, and points of interest (POI). It ultimately limits their ability to work with the concept of place. In this case, GIS should detect the place functionality that does not necessarily exist simply and clearly in the stored data.2. Materials and MethodsTo address these issues, this paper aims to extract place functionality based on analysis of user-generated textual contents. In order to achieve this goal, first places and user’s reviews about places in TripAdvisor website are collected through web crawling. The advantage of these data over other place-based data is their independence from formal descriptions of place. These data were collected in October 2020, and only English reviews are considered. New York City (NYC) is selected as our case study area. At first, for each place type, we extracted all corresponding places. Then, for each place, we extracted a maximum of 1000 top reviews. To prepare data, places without geographic coordinates, places out of the study area, duplicates or places whose type is unknown are removed. There are five types of place categories on TripAdvisor, including Attraction, Food Serving Place, Hotel, Shop, and Vacation Rental. Then, different natural language processing (NLP) methods are used to preprocess the reviews. First, each review is converted to lower case and tokenized, then punctuations and stop words are removed. Afterward, all tokens are stemmed and lemmatized. In the next step, proper features should be selected for knowledge discovery. We use a bag-of-words (BoW) feature selection method which features values are weighted using TF-IDF scores for each user’s review. Finally, in a supervised method, these values and place functionalities are trained using a logistic regression classifier to predict place functionality on the test dataset.3. Results and DiscussionWe randomly assigned 75% of the data set to train the model and 25% to test the results. Finally, the results are evaluated using common machine learning evaluation measures by computing confusion-matrix. The evaluation results demonstrate that the overall accuracy of the proposed method is about 96% which is remarkable. For Food Serving Place, the predictions are so close to reality that in 98% of cases the algorithm was able to correctly predict Food Serving Places. Also, about 0.8% of them are considered as Attractions. In the case of Hotels, the accuracy is 97%. However, about 1.8% of Hotels are incorrectly categorized as Food Serving Places. Attractions are also 93% correctly predicted and about 3.8% of them are mistaken for Food Serving Places. In the case of Shop, the accuracy is about 74%, because the number of reviews related to this type of functionality is lower, although this issue has been partially resolved by weighting the samples. Secondly, in many cases, people visit the shopping malls for entertainment and not just shopping, which has led to about 15% of Shops being classified as Attractions. Also, about 11% of these Shops are considered as Food Serving Places. One of the most important reasons for this is the action of buying food in these places, which is a kind of purchase. In addition, in some shopping malls there are places to serve drink and food. Since the reviews of the Vacation Rentals was less than other functionalities, the lowest accuracy (about 65%) is related to them. In 25% of cases, Vacation Rentals are classified as Hotels. This result is not too far-fetched, as Vacation Rentals and Hotels are very similar in function and are often used to accommodate travelers and tourists. Also, 4.8% and 4.6% of them are classified as Attractions and Food Serving Places, respectively. The maximum precision and F1-score is achieved for Food Serving Places while Vacation Rentals show the least precision and F1-score since their functionality is similar to hotels, however, their results are also reliable and satisfactory.4. conclusionIn this study, we tried to extract the place functionality by analyzing the user-generated textual contents shared on the TripAdvisor website by users. To achieve this purpose, different NLP methods were used to prepare and preprocess the data. The bag-of-words constructed for each user's review was then modeled to a logistic regression classifier, and the place functionality on the test data was predicted. In future works, the efficiency of other feature selection methods as well as other classifiers in extracting place functionality can be evaluated and compared. In addition, the place functionality should be extracted in more detail where different types of attractions can be distinguished.
Mina Karimi; Abolghasem Sadeghi Niaraki; Ali Hosseininaveh Ahmadabdian
Abstract
Extended Abstract Introduction Underground infrastructure such as electricity, gas, telecommunications, water and sewage are managed by different organizations. Since most projects in these organizations require drilling,and imprecise excavations will endanger infrastructure and result in extensive financial ...
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Extended Abstract Introduction Underground infrastructure such as electricity, gas, telecommunications, water and sewage are managed by different organizations. Since most projects in these organizations require drilling,and imprecise excavations will endanger infrastructure and result in extensive financial and physical losses, drilling projects require having accurate information about the infrastructure status. However, reaching accurate position of facilities such as pipes and cables is difficult due to their being concealed underground.Nowadays, ubiquitous computing and new developments in Geospatial Information Systems (GIS) can be an appropriate solution to such problems. This new generation of GIS is called the Ubiquitous Geospatial Information System (UBGIS). New technologies such as Augmented Reality (AR) can visualize this infrastructure on platforms like smart phones or tablets. Such technologies show spatial and descriptive attributes of these utilities more interactively, and thus can be applied as a modern solution for this problem. One of the major features of AR is identifying and locating real-world objects with respect to the person’s head or a camera. To have an accurate Augmented Reality, the position and orientation (pose) of the camera should be estimated with high accuracy. Therefore, exterior orientation parameters of the camera are required for AR and tracking. Different methods are used to calculate these exterior orientation parameters. One of the most common methods applies different sensors,such as Global Positioning System (GPS) and Inertial Measuring Unit (IMU),embedded in smart phones or tablets to calculate these parameters. These sensors include accelerometers, gyroscopes, magnetic sensors and compasses. Althoughsimple and fast, this method is not suitable for accurate cases, because sensors of mobile phones or tabletscannot provide such high accuracy. Vision-based (sometimes called image-based) method is another way of estimating exterior orientation parameters. In this method, fixed or dynamic images are used to determine the position and orientation of camera. The method is more complex and slower, but more accurate than the first one. Materials and Methods Regarding previously mentioned issues, the present article aims to visualize underground infrastructure using both sensor-based and vision-based approaches of Augmented Reality. Since the sensors embedded in a mobile phone or tablet do not provide such an accuracy (an accuracy of a few centimeters considering diameter of pipes and width of streets and pavements), a novel vision-based approach is proposed. In this method, image-based techniques and special kinds of targets, known as coded targets, are used to estimate camera’s position and orientation along with space resection method. In photogrammetry,space resection involves determining the spatial position and orientation of an image based on thesize of ground control points appearing on the image. Since space resection is a nonlinear problem, existing methods involve linearization of the collinearity condition and the use of an iterative process to determine the final solution using the least squares method. The process also requires determination of the initial approximate values of the unknown parameters, some of which must be estimated using another least squares solution. In order to obtain suitable initial values for space resection procedure, data received from GPS, accelerometers, and magnetic sensors are used and a low-pass filter is applied to reduce noise and increase precision. Then, due to improved camera pose parameters, the resulting virtual model is overlaid at its correct real worldplanimetriclocation. The planimetric coordinates are shown graphically on the ground and the Z coordinate (depth) is presented as a descriptive parameter. Results and Discussion Both proposed methods were implemented and tested in an Android Operating System. Camera pose parameters were estimated and the virtual modelwas overlaid at its correct real world planimetric location and shown on camera. Then, the results were compared and evaluatedusingthe well-known photogrammetry software, Agisoft, with the aim of modelling and precise measuring based on basic photogrammetry and machine vision. For sensor-based method, mean accuracy of the position parameters equals 4.2908±3.951 meters and mean accuracy of orientation parameters equals 6.1796±1.478 degrees,whilein vision-based method,these decreases to 0.1227±0.325 meters and 2.2017±0.536 degrees, respectively. Thus, results indicate that the proposed methodimprove accuracy and efficiency of AR technologies. Conclusion Augmented Reality is a technology that can be used to visualize underground facilities. Although,processing in sensor-based methods is sufficiently fast and simple, they lack the precision required for this purpose. Despite the fact that noise elimination and sensor integration using Kalman filter improves accuracy to some degree, it still does not reach the required accuracy. The present article sought to improve the accuracy of augmented reality in underground infrastructureusing targets. Results indicated that the machine vision and vision-based methods improve the accuracy. In drillings, third dimension (accuracy of height measurements) is as crucial as other parameters, thusit is suggested that future researches consider this not as a descriptive parameter, but as a three dimensional parameter to reach 3dimensional visualization.