GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK
This research is development framework for detecting congestion on the urban road network. ATCS <br /> <br /> data (Area Traffic Control System) in Bandung city with traffic volume used in congestion detection <br /> <br /> process. Traffic flow data is colle- cted by vehic...
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id-itb.:211822017-10-02T10:09:51ZGRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK RAMDLANI (NIM: 23514094), APIP Indonesia Theses INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/21182 This research is development framework for detecting congestion on the urban road network. ATCS <br /> <br /> data (Area Traffic Control System) in Bandung city with traffic volume used in congestion detection <br /> <br /> process. Traffic flow data is colle- cted by vehicles detector located at a crossroads within of 15 <br /> <br /> minutes. The data also collects flow direction and location of intersections in the road ne- twork. <br /> <br /> To compute spatial correlation, graph modelling used in the adjacency matrix. Assuming the location <br /> <br /> of the detector as the vertices and the direction of the vehicle as the edge, the graph modeled <br /> <br /> with vehicle’s detector location and the flow direction at nine locations on road nework. Results, <br /> <br /> graph repre- sented matrix for easiest way to correlation calculation. The adjacency matrix used <br /> <br /> consists of 3 matrices in each period of time, which describes the order of spatial distances <br /> <br /> traveled by vehicle at the intersection location. To calculate spatial correlation, the <br /> <br /> autocorrelation function and the cross-correlation fun- ction which are derived from Pearson’s <br /> <br /> simple correlation is used to looking influence at each location on road network. Spatial <br /> <br /> correlation is performed on 4 (four) time periods, namely: at 24 hour (00: 00-24: 00), AM <br /> <br /> Peak(06: <br /> <br /> 00-09: 00), Interpeak (11: 00-14: 00) and PM peak(16: 00-19: 00) The result of calculation of <br /> <br /> spatial correlation, shows the existence of seasonal pattern on the autocorrelation results even <br /> <br /> though the value scale is getting smaller as it increases time lags. This provides that the process <br /> <br /> of calculating cross- correlation functions and it can be concluded that the volume of vehicles at <br /> <br /> each location that are connected in the road network can be known by making observations in the <br /> <br /> time series of previous seasonal periods. observing conges- tion levels intersection location based <br /> <br /> on Level of Service is used ti proove teh result of congestion detection. The conclusion that can <br /> <br /> be formulated that graph modeling is needed to simplify the spatial correlation calculation process <br /> <br /> by performing the graph representation into a matrix. The Simpson rules on cross-correlation <br /> <br /> results, can be detected congestion at intersection locations on the road network to find the most <br /> <br /> critically locations causing congestion on <br /> <br /> the road network at time periods. <br /> text |
| institution |
Institut Teknologi Bandung |
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| continent |
Asia |
| country |
Indonesia Indonesia |
| content_provider |
Institut Teknologi Bandung |
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| language |
Indonesia |
| description |
This research is development framework for detecting congestion on the urban road network. ATCS <br />
<br />
data (Area Traffic Control System) in Bandung city with traffic volume used in congestion detection <br />
<br />
process. Traffic flow data is colle- cted by vehicles detector located at a crossroads within of 15 <br />
<br />
minutes. The data also collects flow direction and location of intersections in the road ne- twork. <br />
<br />
To compute spatial correlation, graph modelling used in the adjacency matrix. Assuming the location <br />
<br />
of the detector as the vertices and the direction of the vehicle as the edge, the graph modeled <br />
<br />
with vehicle’s detector location and the flow direction at nine locations on road nework. Results, <br />
<br />
graph repre- sented matrix for easiest way to correlation calculation. The adjacency matrix used <br />
<br />
consists of 3 matrices in each period of time, which describes the order of spatial distances <br />
<br />
traveled by vehicle at the intersection location. To calculate spatial correlation, the <br />
<br />
autocorrelation function and the cross-correlation fun- ction which are derived from Pearson’s <br />
<br />
simple correlation is used to looking influence at each location on road network. Spatial <br />
<br />
correlation is performed on 4 (four) time periods, namely: at 24 hour (00: 00-24: 00), AM <br />
<br />
Peak(06: <br />
<br />
00-09: 00), Interpeak (11: 00-14: 00) and PM peak(16: 00-19: 00) The result of calculation of <br />
<br />
spatial correlation, shows the existence of seasonal pattern on the autocorrelation results even <br />
<br />
though the value scale is getting smaller as it increases time lags. This provides that the process <br />
<br />
of calculating cross- correlation functions and it can be concluded that the volume of vehicles at <br />
<br />
each location that are connected in the road network can be known by making observations in the <br />
<br />
time series of previous seasonal periods. observing conges- tion levels intersection location based <br />
<br />
on Level of Service is used ti proove teh result of congestion detection. The conclusion that can <br />
<br />
be formulated that graph modeling is needed to simplify the spatial correlation calculation process <br />
<br />
by performing the graph representation into a matrix. The Simpson rules on cross-correlation <br />
<br />
results, can be detected congestion at intersection locations on the road network to find the most <br />
<br />
critically locations causing congestion on <br />
<br />
the road network at time periods. <br />
|
| format |
Theses |
| author |
RAMDLANI (NIM: 23514094), APIP |
| spellingShingle |
RAMDLANI (NIM: 23514094), APIP GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| author_facet |
RAMDLANI (NIM: 23514094), APIP |
| author_sort |
RAMDLANI (NIM: 23514094), APIP |
| title |
GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| title_short |
GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| title_full |
GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| title_fullStr |
GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| title_full_unstemmed |
GRAPH ANALYSIS FOR CONGESTION DETECTION ON ROAD NETWORK |
| title_sort |
graph analysis for congestion detection on road network |
| url |
https://digilib.itb.ac.id/gdl/view/21182 |
| _version_ |
1822920091560312832 |