Real-time velocity optimization to minimize energy use in passenger vehicles

Thomas Levermore; M. Necip Sahinkaya; Yahya Zweiri; Ben Neaves

doi:10.3390/en10010030

Real-time velocity optimization to minimize energy use in passenger vehicles

Thomas Levermore, M. Necip Sahinkaya, Yahya Zweiri, Ben Neaves

Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Energy use in internal combustion engine passenger vehicles contributes directly to CO₂ emissions and fuel consumption, as well as producing a number of air pollutants. Optimizing the vehicle velocity by utilising upcoming road information is an opportunity to minimize vehicle energy use without requiring mechanical design changes. Dynamic programming is capable of such an optimization task and is shown in simulation to produce fuel savings, on average 12%, compared to real driving data; however, in this paper it is also applied in real time on a Raspberry Pi, a low cost miniature computer, in situ in a vehicle. A test drive was undertaken with driver feedback being provided by a dynamic programming algorithm, and the results are compared to a simulated intelligent cruise control system that can follow the algorithm results precisely. An 8% reduction in fuel with no loss in time is reported compared to the test driver.

Original language	British English
Article number	30
Journal	Energies
Volume	10
Issue number	1
DOIs	https://doi.org/10.3390/en10010030
State	Published - 2017

Keywords

Dynamic programming
Fuel
Fuel consumption
Optimization

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3390/en10010030

Cite this

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abstract = "Energy use in internal combustion engine passenger vehicles contributes directly to CO2 emissions and fuel consumption, as well as producing a number of air pollutants. Optimizing the vehicle velocity by utilising upcoming road information is an opportunity to minimize vehicle energy use without requiring mechanical design changes. Dynamic programming is capable of such an optimization task and is shown in simulation to produce fuel savings, on average 12%, compared to real driving data; however, in this paper it is also applied in real time on a Raspberry Pi, a low cost miniature computer, in situ in a vehicle. A test drive was undertaken with driver feedback being provided by a dynamic programming algorithm, and the results are compared to a simulated intelligent cruise control system that can follow the algorithm results precisely. An 8% reduction in fuel with no loss in time is reported compared to the test driver.",

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AU - Levermore, Thomas

AU - Sahinkaya, M. Necip

AU - Zweiri, Yahya

AU - Neaves, Ben

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Y1 - 2017

N2 - Energy use in internal combustion engine passenger vehicles contributes directly to CO2 emissions and fuel consumption, as well as producing a number of air pollutants. Optimizing the vehicle velocity by utilising upcoming road information is an opportunity to minimize vehicle energy use without requiring mechanical design changes. Dynamic programming is capable of such an optimization task and is shown in simulation to produce fuel savings, on average 12%, compared to real driving data; however, in this paper it is also applied in real time on a Raspberry Pi, a low cost miniature computer, in situ in a vehicle. A test drive was undertaken with driver feedback being provided by a dynamic programming algorithm, and the results are compared to a simulated intelligent cruise control system that can follow the algorithm results precisely. An 8% reduction in fuel with no loss in time is reported compared to the test driver.

AB - Energy use in internal combustion engine passenger vehicles contributes directly to CO2 emissions and fuel consumption, as well as producing a number of air pollutants. Optimizing the vehicle velocity by utilising upcoming road information is an opportunity to minimize vehicle energy use without requiring mechanical design changes. Dynamic programming is capable of such an optimization task and is shown in simulation to produce fuel savings, on average 12%, compared to real driving data; however, in this paper it is also applied in real time on a Raspberry Pi, a low cost miniature computer, in situ in a vehicle. A test drive was undertaken with driver feedback being provided by a dynamic programming algorithm, and the results are compared to a simulated intelligent cruise control system that can follow the algorithm results precisely. An 8% reduction in fuel with no loss in time is reported compared to the test driver.

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KW - Fuel

KW - Fuel consumption

KW - Optimization

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Real-time velocity optimization to minimize energy use in passenger vehicles

Abstract

Keywords

UN SDGs

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