Algorithms for Multi-Criteria Boundary Labeling

Computer Graphics Forum

2019

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External labeling is frequently used for annotating features in graphical displays and visualizations, such as technical illustrations, anatomical drawings, or maps, with textual information. Such a labeling connects features within an illustration by thin leader lines with their labels, which are placed in the empty space surrounding the image. Over the last twenty years, a large body of literature in diverse areas of computer science has been published that investigates many different aspects, models, and algorithms for automatically placing external labels for a given set of features. This state‐of‐the‐art report introduces a first unified taxonomy for categorizing the different results in the literature and then presents a comprehensive survey of the state of the art, a sketch of the most relevant algorithmic techniques for external labeling algorithms, as well as a list of open research challenges in this multidisciplinary research field.

Section: State Of the Artmentioning

confidence: 99%

“…We assume | A | ≥ | F |, and that the cost function rates single labels. Similar to Benkert et al [BHKN09] we define the drawing area of a sub‐instance of that problem setting by a simple polygon specified by two point features p 1 , p 2 and two reference points a 1 , a 2 ; see Fig. 7a.…”

Section: Labeling Techniquesmentioning

confidence: 99%

External Labeling Techniques: A Taxonomy and Survey

Bekos¹,

Niedermann

Computer Graphics Forum

2019

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“…Instead of requiring that every frame of the animation must be a crossing-free labeling, we remove crossings only when the user stops moving the map view; this can be done in O(n log n) time [6]. Upon resumption of the movement, we keep the current order of the labels until the next break.…”

Section: Discussionmentioning

confidence: 98%

“…This problem is known to be NP-hard and many heuristics and approximation algorithms exist, see [19] and the extensive bibliography on map labeling maintained by Wolff and Strijk [20]. The (static) boundary labeling problem was first introduced as an algorithmic problem by Bekos et al [5] and subsequently studied in different settings for rectilinear and diagonal leader shapes with one or two bends and label positions on one, two, or four sides of the map [3,6,14]; placing the labels in multiple columns on one side of the map was also considered [4]. Still, all previous results assume that labels should be as large as possible.…”

Section: Related Workmentioning

confidence: 99%

Dynamic one-sided boundary labeling

Proceedings of the 18th SIGSPATIAL International Conference on Advances in Geographic Information Systems

Polishchuk

Sysikaski

2010

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In boundary labeling, features on a map are connected to a stack of labels on the map boundary, using simple polylines called leaders. We consider the setting that the labels are axis-aligned non-overlapping rectangles placed on one side of the map, and leaders are rectilinear polylines with at most one bend. The goal is to find a labeling that minimizes the total length of the leaders.We introduce three extensions of the one-sided boundary labeling problem: (i) a dynamic setting for continuous scale changes, (ii) a clustered setting for multiple label stacks, and (iii) a combined dynamic clustered setting. We obtain the following results:• Optimal label placement as a function of map scale can be computed in O(n log n + σ log n) time, where σ is the number of "combinatorially different" labelings that occur during zooming. • In a map with fixed scale, an optimal clustered label placement can be found in O(n log n) time. • In O(n log 2 n + γ log n) time one can build a structure of size O(γ) representing the optimal clustered label placement for all possible map scales; here γ is, again, the number of combinatorially different labelings.We further extend our basic model to the case where labeled features enter or leave the viewport due to map panning and zooming. Our algorithms are based on combining standard computational-geometry tools and have been implemented in a Java applet (available online), which indicates that the algorithms are fast enough for interactive use without delays.

“…Their main objective was to minimize the total leader length, but they also presented an algorithm for minimizing the number of bends in one-sided opo-labeling. Benkert et al [5] studied algorithms for oneand two-sided po-and do-labeling with arbitrary leaderdependent cost functions (including total length and number of bends); the algorithms were implemented and evaluated experimentally. Bekos et al [1] presented algorithms for combinations of more general octilinear leaders of types do, od, and pd and labels on one, two, and four sides of R. For uniform labels the algorithms are polynomial, whereas the authors showed NP-completeness for a variant involving non-uniform labels.…”

Section: Related Workmentioning

confidence: 99%

Boundary-labeling algorithms for panorama images

Gemsa

Haunert

Proceedings of the 19th ACM SIGSPATIAL International Conference on Advances in Geographic Information Systems

2011

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Boundary labeling deals with placing annotations for objects in an image on the boundary of that image. This problem occurs frequently in situations where placing labels directly in the image is impossible or produces too much visual clutter. Previous algorithmic results for boundary labeling consider a single layer of labels along some or all sides of a rectangular image. If, however, the number of labels is large or labels are too long, multiple layers of labels are needed.In this paper we study boundary labeling for panorama images, where n points in a rectangle R are to be annotated by disjoint unit-height rectangular labels placed above R in k different rows (or layers). Each point is connected to its label by a vertical leader that does not intersect any other label. We present polynomial-time algorithms based on dynamic programming that either minimize the number of rows to place all n labels, or maximize the number (or total weight) of labels that can be placed in k rows for a given integer k. For weighted labels, the problem is shown to be (weakly) NP-hard, and we give a pseudo-polynomial algorithm to maximize the weight of the selected labels. We have implemented our algorithms; the experimental results show that solutions for realistically-sized instances are computed instantaneously.