Feasibility of Using Grammars to Infer Room Semantics
<p>Three typical plans of research buildings.</p> "> Figure 2
<p>Semantic division of research buildings.</p> "> Figure 3
<p>An example of semantic division of research buildings. (<b>a</b>) two building units in a floor. (<b>b</b>) corridors, halls, and enclosed zones in each building unit (<b>c</b>) type of each zone (<b>d</b>) single room types in each zone.</p> "> Figure 4
<p>Predicates used in this work.</p> "> Figure 5
<p>Workflow of proposed algorithm.</p> "> Figure 6
<p>A simplified floor plan with three rooms.</p> "> Figure 7
<p>Procedure of creating parse forest by using bottom-up methods. (<b>a</b>) procedure of constructing first parse tree (<b>b</b>) procedure of constructing second parse tree (<b>c</b>) procedure of constructing third parse tree.</p> "> Figure 7 Cont.
<p>Procedure of creating parse forest by using bottom-up methods. (<b>a</b>) procedure of constructing first parse tree (<b>b</b>) procedure of constructing second parse tree (<b>c</b>) procedure of constructing third parse tree.</p> "> Figure 8
<p>Pruning incomplete trees from parse forest.</p> "> Figure 9
<p>Proportion of different room types in training rooms.</p> "> Figure 10
<p>Distribution of test buildings.</p> "> Figure 11
<p>Floor plans (<b>a</b>–<b>o</b>) used for test.</p> "> Figure 11 Cont.
<p>Floor plans (<b>a</b>–<b>o</b>) used for test.</p> "> Figure 12
<p>Confusion matrix of classification result.</p> "> Figure 13
<p>Parse tree with highest probability for floor-plan (d).</p> ">
Abstract
:1. Introduction
- (1)
- To the best of our knowledge, this is the first time inferring the types of rooms by using grammars given geometric maps.
- (2)
- To a certain degree, we prove that grammars can benefit semantic enrichment.
2. Related Works
3. Formal Representation of Layout Principles of Research Buildings
3.1. Definition of Research Buildings
3.2. Hierarchical Semantic Division of Research Buildings
3.3. Constrained Attribute Grammar
3.4. Predicates
- edgeAdj (,): Object is adjacent to object via a shared edge without inclusive relationships between and .
- inclusionAdj (,,): Object includes object and they are connected through an internal door .
- withExtDoor(): Object has an external door connected to corridors.
- onExtWall (): Object is at the edge of external walls.
- inCenter (): Most of the rooms in object (zone) is not located at the external walls of buildings.
- conByIntDoor(, ): Multiple objects are connected through internal doors .
- isTripleLoaded(): Building owns a triple-loaded circulation system.
- isDoubleLoaded(): Building owns a double-loaded circulation system.
- formFullArea(): Multiple objects form a complete area (e.g., a perimeter area or central dark zone), including all the primitive rooms and internal doors.
3.5. Defined Rules
- A1:
- A room object can be assigned with one of the eight types. When applying this rule, Bayesian inference methods are used to calculate the initial probability of belonging the room to corresponding type.
- A2:
- A Toilet object is generated by merging one to three room objects when they satisfy the predicate conByIntDoor and only one of the room objects has an external door. Bayesian inference techniques are used to calculate the mean initial probability of each room to a toilet.
- A3:
- Toilet, Copy, Storage, Kitchen, Lounge, Computer, Lecture, and Library objects are interpreted as Ancillary objects.
- A4:
- A Library object is generated by merging a couple of room objects when they are connected by internal doors. Bayesian inference methods are used to calculate the mean probability of each room belonging to a library.
- A5:
- A couple of lecture objects that are adjacent or connected by internal doors can be interpreted as an academic Zone.
- A6:
- A Library object is interpreted as an academic Zone.
- A7:
- A Lab object is generated by merging a single room and an optional internal room included by when . is on external walls. The Bayesian inference method is used to calculate the initial probability of belonging to a lab.
- A8:
- A LGroup object is generated by merging at least one Lab object and optional Support objects when they are connected by internal doors.
- A9:
- A lab Zone is generated by merging multiple adjacent LGroup objects.
- A10:
- A room object with an optional internal room contained by can be explained as an Office object if has an external door. The Bayesian inference method is used to calculate the initial probability of belonging to an office.
- A11:
- An office Zone can be generated by merging multiple Office objects if they are adjacent or connected through internal doors.
- A12:
- A Center object can be generated by combining at most three Ancillary objects and optional adjacent or connected Support objects if the generated object satisfies the predicate formFullArea. If no Support objects exist, the type of the generated Center object is assigned ancillary otherwise support.
- A13:
- A CZone object can be generated by combining at most three Ancillary objects and a Zone object if the generated object satisfies the predicate formFullArea.
- A14:
- An office-centered or academic-centered building unit can be generated by merging at least one CZone object with the type of office, at most two Center objects with the type of ancillary, and at most two CZone objects with the type of academic if the generated object satisfies the predicate formFullArea.
- A15:
- A lab-centered building unit can be generated by merging at least one CZone object with the type of lab, at least one CZone object with the type of office, and optional CZone objects with the type of academic if the generated object satisfies the predicate formFullArea. Note that if the building unit has a triple-loaded circulation system (with central dark areas), there exists at least one Center object with the type of support.
- A16:
- A Building object can be generated by combining all the BUnit objects if they are adjacent.
4. Algorithm of Inferring Room Types
4.1. Workflow
4.2. Bayesian Inference
4.3. Compute Parse Forest
4.3.1. Partition Grammar Rules into Layers
- (1)
- Build dependency graph. Traversal each rule and draw a direct edge from current rule to the rules whose left-hand objects intersect the right-hand objects of this rule. If the right-hand objects of a rule include only primitive objects (e.g., rooms and doors), it is treated as a free rule.
- (2)
- Delete free rules. Put the free rules at the lowest layer and then delete the free rules and all the edges connecting them from the graph.
- (3)
- Handle new free rules. Identify new free rules and put them at the next layer. Similarly, delete the free rules and the corresponding edges. Repeat this step until no rules exist in the graph.
4.3.2. Apply Rules
- (1)
- Initialize an object list with the primitives and set the current layer as the first layer.
- (2)
- Apply all the rules at the current layer to the objects in the list to generate superior objects.
- (3)
- Fill the child list of the generated object with the inferior objects that form the generated objects.
- (4)
- Assign a probability value to newly generated objects. When applying rules 1, 2, 4, 7, and 10, the probability is estimated through the Bayesian inference. Otherwise, we assign a probability of one to the generated objects.
- (5)
- Add the newly generated objects to the object list.
- (6)
- Move to the next layer and repeat steps (2)–(6).
- (7)
- Create a root node and add all the Building objects to its child list.
Procedure = ComputeParsingForest (,G); Input: // partitioned rules. denotes the number of layers. G // all the primitives: rooms and internal doors Output: // parse forest |
begin for to do for each rule do end end for each object do if the type of is a Building end end end |
4.4. Calculating Probability
5. Experiments
5.1. Training Data
5.2. Testbeds
5.3. Experimental Results
6. Discussions
7. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
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Floor Plan | Lab-Centered | Office-Centered | Academic-Centered |
---|---|---|---|
(a) | 1 | 0 | 1 |
(b) | 1 | 1 | 0 |
(c) | 0 | 0 | 2 |
(d) | 1 | 0 | 0 |
(e) | 1 | 0 | 0 |
(f) | 1 | 0 | 0 |
(g) | 1 | 0 | 0 |
(h) | 0 | 1 | 0 |
(i) | 0 | 1 | 2 |
(j) | 0 | 1 | 1 |
(k) | 0 | 1 | 0 |
(l) | 0 | 1 | 1 |
(m) | 1 | 0 | 0 |
(n) | 0 | 1 | 0 |
(o) | 0 | 2 | 0 |
Floor Plan | Identification Accuracy | Number of Rooms | Time Consumption(s) |
---|---|---|---|
Floor plan (a) | 0.82 | 39 | 8.05 |
Floor plan (b) | 0.90 | 29 | 3.93 |
Floor plan (c) | 0.80 | 10 | 2.40 |
Floor plan (d) | 0.95 | 21 | 3.10 |
Floor plan (e) | 1.00 | 43 | 27.02 |
Floor plan (f) | 0.94 | 48 | 7.18 |
Floor plan (g) | 0.97 | 32 | 459.00 |
Floor plan (h) | 0.74 | 19 | 3.68 |
Floor plan (i) | 0.86 | 22 | 4.14 |
Floor plan (j) | 0.82 | 22 | 4.45 |
Floor plan (k) | 0.74 | 27 | 2.62 |
Floor plan (l) | 0.69 | 13 | 5.66 |
Floor plan (m) | 0.38 | 34 | 13.12 |
Floor plan (n) | 0.86 | 36 | 2.33 |
Floor plan (o) | 1.00 | 13 | 2.09 |
Overall | 0.84 | 408 | 548 |
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Hu, X.; Fan, H.; Noskov, A.; Zipf, A.; Wang, Z.; Shang, J. Feasibility of Using Grammars to Infer Room Semantics. Remote Sens. 2019, 11, 1535. https://doi.org/10.3390/rs11131535
Hu X, Fan H, Noskov A, Zipf A, Wang Z, Shang J. Feasibility of Using Grammars to Infer Room Semantics. Remote Sensing. 2019; 11(13):1535. https://doi.org/10.3390/rs11131535
Chicago/Turabian StyleHu, Xuke, Hongchao Fan, Alexey Noskov, Alexander Zipf, Zhiyong Wang, and Jianga Shang. 2019. "Feasibility of Using Grammars to Infer Room Semantics" Remote Sensing 11, no. 13: 1535. https://doi.org/10.3390/rs11131535
APA StyleHu, X., Fan, H., Noskov, A., Zipf, A., Wang, Z., & Shang, J. (2019). Feasibility of Using Grammars to Infer Room Semantics. Remote Sensing, 11(13), 1535. https://doi.org/10.3390/rs11131535