From finance to ITS: traffic data fusion based on Markowitz' portfolio theory

Neumann, Thorsten; Ebendt, Rüdiger; Kuhns, Günter

doi:10.1002/atr.1351

Cited by 10 publications

(4 citation statements)

References 23 publications

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“…Further, it is quite interesting that specifically improvements are made in case homogeneous sensors (or sensors that provide similar accuracies) are used. Although, usually each additional sensor (in case of an unbiased sensor it almost does not matter how good it is [15]) contributes by improving the fused data in the stationary case; however, in terms of adaptive, non-stationary data fusion it does matter, which types and accuracies of sensors are combined.…”

Section: Discussionmentioning

confidence: 99%

“…In case of experiment 3 stationary data fusion is superior to adaptive fusion independently of the sensors applied. • Although it is expected that any additional sensor improves the accuracy and reliability of the resulting data (see [15] in case of unbiased sensors), it is not the case for adaptive fusion. The combination of an accurate sensor (e.g.…”

Section: E Evaluation Of Adaptive Vs Stationary Data Fusionmentioning

confidence: 99%

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Fusion based estimation of the a-priori probability distribution of unknown non-stationary processes

Junghans

Leich

2019

2019 22th International Conference on Information Fusion (FUSION)

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Non-stationary processes can be hard to handle, particular if one would like to know their characterizing time dependent probability functions. In this paper the a-priori probability distributions of unknown non-stationary processes are estimated with different combinations of weakly coupled sensors. For quantification of the unknown a-priori probabilities Bayesian Networks (BN) are adopted for data fusion and Dirichlet functions are applied on non-stationary, time-dependent maximum likelihood (ML) parameter learning. In several experiments the adaption of the non-stationary a-priori probability density functions is shown and the accuracy of data fusion regarding the underlying process variables with different characteristics are determined quantitatively. It is shown that the proposed algorithm can improve data fusion in case conditions for specific process and sensor characteristics are met.

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Section: Discussionmentioning

confidence: 99%

Section: E Evaluation Of Adaptive Vs Stationary Data Fusionmentioning

confidence: 99%

Fusion based estimation of the a-priori probability distribution of unknown non-stationary processes

Junghans

Leich

2019

2019 22th International Conference on Information Fusion (FUSION)

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“…[5] And Neumann says the problem of parameter calibration is solved by applying an advanced tool for such floating car data systems, called "selfevaluation". [6] The research of this article focuses on the application side, through the flexible use of a variety of theories to provide the industry with an excellent portfolio of risky assets. It flexibly combines Markowitz theory with real stocks to achieve a breakthrough leap.…”

Section: Introductionmentioning

confidence: 99%

Industry Asset Allocation Portfolio Analysis

Zhu¹

2022

BCPBM

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Since the beginning of the 21st century, there have been many excellent fund managers, but excellent asset portfolios are rare. Therefore, it is of great interests to implement in-depth investigations on this issue. In this paper, Markowitz model and Index model are selected to measure the returns and volatility of ten different excellent assets to get a better result. At the same time, according to the preferences of different customers, five different constraints are selected to meet the characteristics of more groups. Based on this, this paper optimizes the asset portfolio. This result shows that: First, when the Markowitz model and the Index model are combined with the capital market line and the efficient frontier, it is very effective to apply it to the risk asset portfolio. Second, Alaska Air Group and Hawaiian Holdings tend to be short under various constraints, while Wells Fargo is the opposite. It is of great significance to the research on the optimal allocation of financial assets in the industry.

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“…Neumann et al [7] addressed the traffic data fusion problem of using multiple data sources to make better estimation of travel times instead of using a single data source. Based on Markowitz' portfolio theory in finance, they proposed an optimized weighted-mean approach to determine the optimal fusion of multiple data sources.…”

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confidence: 99%

Special issue: Smart transportation: Theory and practice

Chen

Lam²

2015

J of Advced Transportation

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Transportation network, for providing mobility to all travelers, is an indispensable component of daily life in our society. With rapid urbanization and economic development, the continuously increasing travel demands in urban areas have resulted in serious traffic congestion problems in many large cities over the world. The adverse impacts of traffic congestion include not only considerably increased journey times and vehicular traffic delays but also fuel consumption and air pollution problems [1,2]. The conventional method for alleviating traffic congestion problems is to build more road infrastructures and/or expand the existing transportation networks. Yet, the use of the conventional method is increasingly restricted in most urban areas, because of the scarcity of land and public funds. To meet the challenges of providing adequate mobility in urban areas, smarter solutions are required by the best use of existing transportation facilities.In recent years, the advances of sensing and information technologies have produced a variety of spatiotemporal big data for travel in urban areas [3][4][5][6]. The data sources include taxi trajectories, mobile phone records, smart card data, social media data, and various user-generated geographical information. These spatiotemporal big data for travel consist of the daily activity pattern and travel behaviors of travelers together with their interactions on transport-related environment. These extensive big datasets involve a large sample size of the total population. Such huge spatiotemporal data have offered a golden opportunity for developing advanced models and algorithms to improve transportation safety, enhance network efficiency and reliability, and reduce environmental impacts. The spatiotemporal big data together with advanced models and algorithms have a great potential to drive cities toward smart transportation.This special issue is devoted to the dissemination of the state-of-the-art research on the smart transportation topics ranging from theory to practice. In total, eight papers are included in this special issue and are briefly summarized in the succeeding text.Several of the papers included in this special issue present novel approaches to estimate and/or predict transportation network conditions using the emerging spatiotemporal big data that are collected from multiple sources. Neumann et al. [7] addressed the traffic data fusion problem of using multiple data sources to make better estimation of travel times instead of using a single data source. Based on Markowitz' portfolio theory in finance, they proposed an optimized weighted-mean approach to determine the optimal fusion of multiple data sources. The similarities and differences between the traffic data fusion problem and portfolio investment problem were discussed. The benefits of using negative weights and the ways of reducing systematic errors in the context of traffic data fusion were analyzed from the perspective of Markowitz' portfolio theory. Real-world floating car data of two independe...

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From finance to ITS: traffic data fusion based on Markowitz' portfolio theory

Cited by 10 publications

References 23 publications

Fusion based estimation of the a-priori probability distribution of unknown non-stationary processes

Fusion based estimation of the a-priori probability distribution of unknown non-stationary processes

Industry Asset Allocation Portfolio Analysis

Special issue: Smart transportation: Theory and practice

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