Hans Peter Schwefel scite author profile

Abstract-Prediction of availability of physical services can be a valuable addition to transportation systems operation. In this paper we are focusing on estimation of public transport occupancy (PTO), or more specifically, on estimating bus passenger load, i.e., the number of people on the bus. This information can be used by bus operators as input to the analysis of bus routes' efficiency, or to provide an app indicating passenger load. PTO estimation based on collecting WiFi probes emitted by WiFi enabled devices is cheap and easy to install. This paper presents a prototype implementation of this method, analysis of the collected data and of the estimation algorithm accuracy. Analysis of passenger load in a bus has indicated that there are two main challenges of the estimation using WiFi probes. The algorithm provides overestimation due to inclusion of WiFi devices that are outside the bus and underestimation due to exclusion of people without an active WiFi enabled device or by missing out probes in the detection algorithm from devices carried on board. We have shown how by fine-tuning parameters of the algorithm the probes received from people outside the bus can be filtered out thereby reducing the severity of the underestimation problem. The typical approach to combat the overestimation problem is to make the adjustments based on a statistical ratio of people possessing a WiFi enabled smart device over the whole population.

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<title>Impact of aggregated self-similar on/off traffic on delay in stationary queueing models</title>

Schwefel¹,

Lipsky²

1999

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CyNC: A MATLAB/SimuLink Toolbox for Network Calculus

Schiøler¹,

Schwefel²,

Bøgsted³

2007

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This paper presents a graphical integrated modelling and performance-analysis tool based on deterministic network calculus (DNC) and implemented as an open source toolbox for the MATLAB/SimuLink environment. The paper introduces briefly the main concepts from network calculus and especially recent results for systems with cyclic dependencies, which appear in cases of cyclic data/work flow or counter directional resource and work flows. A number of network element types are supported including various arbitration/scheduling disciplines such as: Fixed Priorities, FIFO, TDMA, round robin/token passing and EDF along with packetization, flow control and flow convergence. These are all presented in the paper together with auxiliary tools like worst case backlog and delay calculations. Implementation details of general interest are presented along with illustrative examples demonstrating the virtues of the separate modelling elements and the overall tool framework. Discussion is provided concerning issues in system stability and the ability of DNC to provide usefull estimates of stability limits. Likewise current activities to support synchronous communication and flow control within the tool are presented.

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Network condition based adaptive control and its application to power balancing in electrical grids

Pedersen

Findrik

Sloth

et al. 2017

Sustainable Energy, Grids and Networks

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