2012 
; wall 
land 
wall 
  
iling 
  
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B4, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
2.3 Results 
Partial experimental results are as follows. Figure 10 presents 
one of the results from our outdoor experiment for evaluation of 
the availability when GNSS receivers including GPS, 
GLONASS and QZSS are integrated in dense urban areas. 
Figure 11 shows a result from pedestrian tracking taken from 
laser scanner data in our indoor experiment. This result was 
used as a reference value for evaluating the performance of 
positioning sensors. The accuracy, integrity and continuity of 
each sensor in our experimental environment are summarized in 
Table 2 (although we recognize that the performance of sensor 
system depends on an environment). 
  
  
  
  
$77 Ww s aC n Glass wall 
eo} Ls A Ck ; RS 
Pedestrian trajectory i : 
] 
are dé eene ai ont 
i ^ 
4» 
  
  
  
200 vue 
a "7 . es y 
rc er ih ntl ete en oi Metal and 
glass wall 
-200 i i à i i j 
0 Son 1000 2 1500 2000 2500 
Kami 
Figure 11. Result from pedestrian tracking using laser scanner 
data 
Table 2. Accuracy, integrity and continuity of each sensor in 
the experimental environment 
  
IMES | Light tag | RFID tag 
  
Accuracy 
1 ; : 
(Service area) on 1.5m on 
  
Static | 74.67 % | 26.38 % - 
Move | 83.96 % | 97.70 % - 
  
Continuity 
  
Static | 94.49 % | 57.30 % | 100.00 % 
Move | 54.15 % | 51.46 % | 79.75 % 
  
Integrity 
  
  
  
  
  
  
  
3. DISCUSSION 
The first experiment involved a coarse-resolution indoor 
navigation using position data taken at 22 points to investigate 
availability and continuity in an indoor navigation environment. 
The second experiment involved a fine-resolution indoor 
navigation using position data taken at 254 points with electric 
field maps generated from each sensor to investigate accuracy 
and continuity in an indoor navigation environment. The third 
experiment integrated navigation of both indoor and outdoor 
environments to investigate availability and continuity in an 
indoor-outdoor navigation environment. The fourth experiment 
involved outdoor navigation using multiple satellite systems to 
investigate accuracy, availability and integrity. 
Based on the results from our experiments, we can make some 
observations about seamless navigation using multiple 
navigation systems, focusing on the following representative 
issues from our research. The first issue is the improvement of 
availability using multiple navigation systems. We have 
clarified that outdoor positioning of multiple navigation 
satellites has the potential to improve availability in an open- 
sky environment. Indeed, compared with the use of GPS only, 
the use of multiple navigation satellites improved the position 
fix rate by 2096. On the other hand, we also clarified that in a 
dense urban environment, the integrity of navigation decreases 
from 100% to approximately 5096 because of multipath 
interference. In addition, we clarified in our experiment that the 
position fix rate decreases when the number of navigation 
satellites increases. 
The second issue is interference between indoor navigation 
systems. We found that, because of interference, fewer satellite 
signals are received by high-sensitivity GPS receivers when an 
IMES transmitter is located within a 3 m radius of the receiver. 
Therefore, we conclude that the design of IMES transmitter 
arrangements should accommodate this restriction in indoor- 
outdoor border areas for seamless navigation using GPS and 
IMES. 
The third issue is interference between the indoor navigation 
and 3D measurement systems. When the orientation of time-of- 
flight infrared camera is within 40? of the line of sight between 
a lighting tag and a lighting tag receiver, infrared interference 
renders the lighting tag system unavailable. Therefore, for 
human sensing and autonomous robot navigation, we must 
focus on the directional properties of sensors. 
4. SUMMARY 
The initial focus in our research was the construction of a test 
environment for  indoor-outdoor seamless navigation 
experiments. Based on SARPs, we focused on accuracy, 
availability, continuity and integrity to verify the effects of 
seamless navigation under a combination of as many systems 
and sensors as possible. We then conducted data acquisition and 
data analysis in seamless navigation through four integrated 
experiments. Based on the results of our experiments, we 
summarized.some observations about seamless navigation using 
multiple navigation systems. 
References 
[1] Dinesh Manandhar, Seiya Kawaguchi, Masayuki Uchida, Makoto 
Ishii, Hideyuki Torimoto. 2008. IMES for Mobile Users Social 
Implementation and Experiments based on Existing Cellular Phones for 
Seamless Positioning. In: Proceedings of International Symposium 2008 
on GPS-GNSS. 
[2] S. Kogure, M. Sawabe, and M. Kishimoto. 2006. Status of QZSS 
Navigation System in Japan. In: Proceedings of ION GNSS 2006, pp. 
2092-2102. 
Acknowledgements 
This work forms part of a series of experiments conducted by a 
committee in the Institute of Electrical Engineers of Japan 
(IEEJ). This work is partly supported by the Strategic 
Information and Communications R&D Promotion Programme 
(SCOPE) of the Ministry of Internal Affairs and 
Communications, Japan. 
35