TY - GEN
T1 - Dual Error Bounded Trajectory Simplification
AU - Lin, Xuelian
AU - Jiang, Jiahao
AU - Zuo, Yimeng
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2017/5/8
Y1 - 2017/5/8
N2 - Nowadays, various sensors are collecting, storing and transmitting tremendous trajectory data, and it is well-known that raw trajectory data seriously wastes the storage, network band and computing resource. Line simplification (LS) algorithms are effective approaches to attacking this issue by compressing data points in a trajectory to a set of continuous line segments, and are commonly used in practice. LS algorithms in general use the perpendicular Euclidean distance (PED) or synchronous Euclidean distance (SED) of a data point to a proposed generalized line as the condition to discard or retain that data point. In the observation that the PED approach performances well in terms of compression ratios but is not suitable for temporal-spatio queries, while the SED approach is on the contrary, this paper presents a dual distances checking approach that leverages the benefits of approaches PED and SED, and satisfies the varied distance checking requirements. We experimentally verify that our approach is flexible and effective, using two real-life trajectory datasets.
AB - Nowadays, various sensors are collecting, storing and transmitting tremendous trajectory data, and it is well-known that raw trajectory data seriously wastes the storage, network band and computing resource. Line simplification (LS) algorithms are effective approaches to attacking this issue by compressing data points in a trajectory to a set of continuous line segments, and are commonly used in practice. LS algorithms in general use the perpendicular Euclidean distance (PED) or synchronous Euclidean distance (SED) of a data point to a proposed generalized line as the condition to discard or retain that data point. In the observation that the PED approach performances well in terms of compression ratios but is not suitable for temporal-spatio queries, while the SED approach is on the contrary, this paper presents a dual distances checking approach that leverages the benefits of approaches PED and SED, and satisfies the varied distance checking requirements. We experimentally verify that our approach is flexible and effective, using two real-life trajectory datasets.
KW - Error Bounded
KW - Line Simplification
KW - Trajectory Compression
UR - https://www.scopus.com/pages/publications/85019999427
U2 - 10.1109/DCC.2017.23
DO - 10.1109/DCC.2017.23
M3 - 会议稿件
AN - SCOPUS:85019999427
T3 - Data Compression Conference Proceedings
SP - 448
BT - Proceedings - DCC 2017, 2017 Data Compression Conference
A2 - Bilgin, Ali
A2 - Serra-Sagrista, Joan
A2 - Marcellin, Michael W.
A2 - Storer, James A.
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2017 Data Compression Conference, DCC 2017
Y2 - 4 April 2017 through 7 April 2017
ER -