Multi-dimensional Aggregation for Temporal Data

Böhlen, Michael H.; Gamper, Johann; Jensen, Christian S.

doi:10.1007/11687238_18

Cited by 51 publications

(50 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…In a similar vein, the multi-dimensional temporal aggregation operator [2] generalizes previous temporal aggregation operators. Two different semantics are distinguished.…”

Section: Related Workmentioning

confidence: 96%

“…Various forms of temporal aggregation have been studied in the past, including instant temporal aggregation (ITA), moving-window temporal aggregation (MWTA), and span temporal aggregation (STA) [2,7,8,12,13,16]. They differ mainly in how the time line is partitioned.…”

Section: Related Workmentioning

confidence: 99%

“…Figure 7 shows the integrated gPTA algorithm. We adapted the ITA algorithm in [2] to produce the ITA result tuples one by one, which does not change its performance and space requirements. Figure 8 depicts the contents of the heap each time a new ITA result tuple is processed.…”

Section: The Gpta Algorithmmentioning

confidence: 99%

“…Span temporal aggregation (STA) [2,7] allows to control the result size by permitting an application to specify the time intervals for which to report a result tuple, e.g., for each year from 2000 to 2005. For each of these intervals a result tuple is produced by aggregating over all argument tuples that overlap that interval.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Parsimonious temporal aggregation

2011

Self Cite

View full text Add to dashboard Cite

Temporal aggregation is a crucial operator in temporal databases and has been studied in various flavors, including instant temporal aggregation (ITA) and span temporal aggregation (STA), each having its strengths and weaknesses. In this paper we define a new temporal aggregation operator, called parsimonious temporal aggregation (PTA), which comprises two main steps: (i) it computes the ITA result over the input relation and (ii) it compresses this intermediate result to a user-specified size c by merging adjacent tuples and keeping the induced total error minimal; the compressed ITA result is returned as the final result. By considering the distribution of the input data and allowing to control the result size, PTA combines the best features of ITA and STA. We provide two evaluation algorithms for PTA queries. First, the oPTA algorithm computes an exact solution, by applying dynamic programming to explore all possibilities to compress the ITA result and selecting the compression with the minimal total error. It runs in O(n2pc) time and O(n2) space, where n is the size of the input relation and p is the number of aggregation functions in the query. Second, the more efficient gPTA algorithm computes an approximate solution by greedily merging the most similar ITA result tuples, which, however, does not guarantee a compression with a minimal total error. gPTA intermingles the two steps of PTA and avoids large intermediate results. The compression step of gPTA runs in O(np log(c + ?)) time and O(c + ?) space, where ? is a small buffer for ""look ahead"". An empirical evaluation shows good results: considerable reductions of the result size introduce only small errors, and gPTA scales to large data sets and is only slightly worse than the exact solution of PTA. Parsimonious Temporal Aggregation Juozas Gordevičius Johann Gamper Michael BöhlenFree University of Bozen-Bolzano, Italy {gordevicius,gamper,boehlen}@inf.unibz.it ABSTRACTTemporal aggregation is a crucial operator in temporal databases and has been studied in various flavors, including instant temporal aggregation (ITA) and span temporal aggregation (STA), each having its strengths and weaknesses. In this paper we define a new temporal aggregation operator, called parsimonious temporal aggregation (PTA), which comprises two main steps: (i) it computes the ITA result over the input relation and (ii) it compresses this intermediate result to a user-specified size c by merging adjacent tuples and keeping the induced total error minimal; the compressed ITA result is returned as the final result. By considering the distribution of the input data and allowing to control the result size, PTA combines the best features of ITA and STA. We provide two evaluation algorithms for PTA queries. First, the oPTA algorithm computes an exact solution, by applying dynamic programming to explore all possibilities to compress the ITA result and selecting the compression with the minimal total error. It runs in O(n 2 pc) time and O(n 2 ) space, where n is the size of th...

show abstract

“…In a similar vein, the multi-dimensional temporal aggregation operator [2] generalizes previous temporal aggregation operators. Two different semantics are distinguished.…”

Section: Related Workmentioning

confidence: 96%

Section: Related Workmentioning

confidence: 99%

Section: The Gpta Algorithmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Parsimonious temporal aggregation

2011

Self Cite

View full text Add to dashboard Cite

show abstract

“…Since Snodgrass' definition of the temporal data model [14], there has been a large body of work in this area, summarized in [12,4]. This related work covers proposals for index structures (e.g., multi-version Btrees [1]) and algorithms for certain kinds of queries (e.g., temporal aggregation [10,2] and temporal joins [4,15]). In most related work the focus was on disk based structures, optimizing for I/O behavior.…”

Section: Introductionmentioning

confidence: 99%

Storing and processing temporal data in a main memory column store

Kaufmann

Kossmann

2013

Proc. VLDB Endow.

View full text Add to dashboard Cite

Managing and accessing temporal data is of increasing importance in industry. So far, most companies model the time dimension on the application layer rather than pushing down the operators to the database, which leads to a significant performance overhead. The goal of this PhD thesis is to develop a native support of temporal features for SAP HANA, which is a commercial inmemory column store database system. We investigate different alternatives to store temporal data physically and analyze the tradeoffs arising from different memory layouts which cluster the data either by time or by space dimension. Taking into account the underlying physical representation, different temporal operators such as temporal aggregation, time travel and temporal join have to be executed efficiently. We present a novel data structure called Timeline Index and algorithms based on this index, which have a very competitive performance for all temporal operators beating existing best-of-breed approaches by factors, sometimes even by orders of magnitude. The results of this thesis are currently being integrated into HANA, with the goal of being shipped to the customers as a productive release within the next few months.

show abstract