VisitSense: Sensing Place Visit Patterns from Ambient Radio on Smartphones for Targeted Mobile Ads in Shopping Malls
<p>System architecture of VisitSense.</p> "> Figure 2
<p>Overview of VisitSense operation.</p> "> Figure 3
<p>An example of using Event APIs of VisitSense.</p> "> Figure 4
<p>An example of (<b>a</b>) high RSSI fluctuation; (<b>b</b>) frequent AP churn; and (<b>c</b>) wide AP overlap.</p> "> Figure 5
<p>An example of the limitation of Wi-Fi scan similarity-based visit detection: Five adjacent places are visited. The black line represents real visits. The high values (<span class="html-italic">i.e.</span>, 1.5) of the black line indicate staying in a place, and the low values (<span class="html-italic">i.e.</span>, 0) indicate moving between places. The gray line represents the detected visits. The high values (<span class="html-italic">i.e.</span>, 2.0) of the gray line indicate staying in a place, and the low values (<span class="html-italic">i.e.</span>, 0) indicate moving between places. The red line represents the Wi-Fi scan similarity measured by the Tanimoto coefficient. The detected visits are determined by the comparison of the Tanimoto coefficient. The mismatch of the black line and gray line in horizontal axis means that there are many false positives and negatives for detecting the entrance and departure from a place.</p> "> Figure 6
<p>A concept of change-based visit detection.</p> "> Figure 7
<p>An example of a stable AP list (SAL).</p> "> Figure 8
<p>An example of visit detection of VisitSense. Five adjacent places were visited. The black line represents real visits. High values (<span class="html-italic">i.e.</span>, 1.5) of the black line indicates staying in a place, and low values (<span class="html-italic">i.e.</span>, 0) indicates moving between places. The gray line represents detected visits. High values (<span class="html-italic">i.e.</span>, 2.0) of the gray line indicates staying in a place, and low values (<span class="html-italic">i.e.</span>, 0) indicates moving between places. The red line represents the Wi-Fi scan similarity measured by the Tanimoto coefficient, and its values rage from 0 to 1. The yellow line represents the SR of a SAL, and its values ranges from 0 to 1. The blue line represents the CR of a SAL, and its values range from 0 to 1. The green line represents the mobility measured as the RMS of accelerometer values in a time window. This example shows that visiting five adjacent places were well detected by using the proposed algorithm. The details of algorithm are explained in the <a href="#sec4dot1dot2-sensors-15-17274" class="html-sec">Section 4.1.2</a>.</p> "> Figure 9
<p>A Bayesian network for visit prediction.</p> "> Figure 10
<p>Place recognition accuracy. (<b>a</b>) w.r.t similarity algorithms; (<b>b</b>) w.r.t cutoff threshold; and (<b>c</b>) Wi-Fi scan period.</p> "> Figure 11
<p>Visit detection evaluation methodology.</p> "> Figure 12
<p>Visit detection accuracy comparison.</p> "> Figure 13
<p>Visit prediction accuracy w.r.t features.</p> "> Figure 14
<p>User study results (<b>a</b>) the average number of delivered ads; (<b>b</b>) the average rating of delivered ads.</p> ">
Abstract
:1. Introduction
2. Related Work
2.1. Indoor Localization
2.2. Place Detection and Recognition
2.3. Location Prediction
3. System Overview
3.1. System Architecture
3.2. Application Programming Interface
3.3. Visit-Pattern-Aware Mobile Advertising
4. Main Operations
4.1. Visit Detection
4.1.1. Challenge: Noisy Radio Ambience
Algorithm | Formula |
---|---|
Jaccard coefficient | |
Tanimoto coefficient | |
Euclidean distance | |
Pearson correlation coefficient |
4.1.2. Change-Based Visit Detection
4.2. Place Recognition
Noise-Filtered Wi-Fi Fingerprinting
4.3. Visit Prediction
Causality-Based Visit Prediction Model
5. Evaluation
Operation | Parameter | Values (* = default) |
---|---|---|
Wi-Fi Scan Window | Wi-Fi scan period | 10 *, 30 (s) |
Wi-Fi scan window size | 3 * | |
Wi-Fi Ambience Change Detection | Tanimoto similarity threshold | 0.9 * |
Cutoff RSSI threshold | −60, −90 *, −120 (dBm) | |
SR of SAL | 0.4 * | |
Top-k AP RSSI change | 25 dBm * | |
Mobility Change Detection | Accel. sampling frequency | 5 Hz * |
Accel. window size | 300 (1 minute) * | |
Mobility threshold | 3 * | |
Place Recognition | Similarity algorithm | Tanimoto coefficient *, Jarccard coefficient, Euclidean distance, Pearson correlation coefficient |
5.1. Place Recognition Accuracy
5.1.1. Data Collection
5.1.2. Evaluation Results
5.2. Visit Detection Accuracy
5.2.1. Data Collection
5.2.2. Methodology
5.2.3. Evaluation Results
5.3. Visit Prediction Accuracy
5.3.1. Data Collection
Attribute | Number | Ratio | |
---|---|---|---|
Sex | Man | 22 | 29% |
Woman | 52 | 68% | |
N/A | 2 | 3% | |
Age | ~19 | 9 | 12% |
20–29 | 48 | 63% | |
30–39 | 14 | 18% | |
40~ | 2 | 3% | |
N/A | 3 | 4% | |
Job | student | 35 | 46% |
employee | 27 | 36% | |
others | 7 | 9% | |
N/A | 7 | 9% | |
Total | 76 |
5.3.2. Evaluation Results
Classifier | Evaluation Method | Prediction Accuracy (%) | |
---|---|---|---|
Structure Learning Algorithm | |||
Decision tree | N/A | 80% split | 40.54 |
CRFs | N/A | 80% split | 29.72 |
Bayesian networks | Domain knowledge | 80% split | 59.45 |
Repeated Hill Climbing | 80% split | 65 | |
cross-validation | 52.76 | ||
Inferred Causation | 80% split | 55 | |
cross-validation | 51.76 |
5.4. Preliminary User Study
5.4.1. Methodology
Attribute | Number | |
---|---|---|
Sex | Man | 7 |
Woman | 8 | |
Age | 20–22 | 5 |
23–26 | 8 | |
27–29 | 2 | |
Affiliation | KAIST | 8 |
Others | 7 | |
Total | 15 |
5.4.2. Results
6. Limitation and Discussion
7. Conclusions
Author Contributions
Conflicts of Interest
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Kim, B.; Kang, S.; Ha, J.-Y.; Song, J. VisitSense: Sensing Place Visit Patterns from Ambient Radio on Smartphones for Targeted Mobile Ads in Shopping Malls. Sensors 2015, 15, 17274-17299. https://doi.org/10.3390/s150717274
Kim B, Kang S, Ha J-Y, Song J. VisitSense: Sensing Place Visit Patterns from Ambient Radio on Smartphones for Targeted Mobile Ads in Shopping Malls. Sensors. 2015; 15(7):17274-17299. https://doi.org/10.3390/s150717274
Chicago/Turabian StyleKim, Byoungjip, Seungwoo Kang, Jin-Young Ha, and Junehwa Song. 2015. "VisitSense: Sensing Place Visit Patterns from Ambient Radio on Smartphones for Targeted Mobile Ads in Shopping Malls" Sensors 15, no. 7: 17274-17299. https://doi.org/10.3390/s150717274
APA StyleKim, B., Kang, S., Ha, J. -Y., & Song, J. (2015). VisitSense: Sensing Place Visit Patterns from Ambient Radio on Smartphones for Targeted Mobile Ads in Shopping Malls. Sensors, 15(7), 17274-17299. https://doi.org/10.3390/s150717274