A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle Charging
Abstract
:1. Introduction
- Requirements of the stakeholders were identified for reservation in electric mobility.
- An interoperable reference architecture was derived for reserving charging stations.
- Morphological methodology was adopted to instantiate different reservation systems.
- The system’s interoperability was analyzed and verified with the iScore methodology.
- The stakeholder requirements were validated with agent-based simulations.
- A proof-of-concept was implemented for demonstrating ad-hoc reservation.
2. Related Work
2.1. Charging Scheduling
2.2. Charging Station Selection
3. Problem Statement and Objectives
3.1. Requirements for Reservation Systems
3.1.1. Stakeholder Requirements
3.1.2. System Requirement: Interoperability
3.2. Feasible Reservation Types
- Uncertain Ad-Hoc.
- Guaranteed Ad-Hoc.
- Uncertain Planned.
- Guaranteed Planned (Full).
3.3. Research Questions and Contributions
- How to design a generic reference architecture that considers stakeholder requirements, ensures system interoperability, and supports instantiating customized reservation systems?
- What are the benefits for the relevant stakeholders when instantiating different types of reservation systems in practice?
4. Artifact Design and Development
4.1. Reference System Architecture Model
4.1.1. Logical Architecture
4.1.2. Physical System Architecture
4.2. Design Decisions for Reservation System Instances
5. Demonstration and Evaluation
5.1. EMSA-Based Verification of System Interoperability Requirements
5.2. Simulation-Based Validation of Stakeholder Requirements
5.2.1. Scenario Description
- No reservations: Users can not reserve charging station, but the current availability status of the connector/charging station is broadcast to drivers.
- Ad-Hoc reservations: Only one reservation is allowed at a specific connector of a given charging station at any time, as described in Section 3.2. By the morphology in Table 1 from Section 4.2, this instance of reservations can be described as {“Yes”, “No”, “No”, “Limited”, “Yes”, “FCFS”}, referring to supporting “Enforceability” and “Roaming”, having limited information on connector and not supporting “Planning” and “Fee”.
- Planned reservation: Users can make planned reservations at any time and CS can accept multiple reservations for different periods at the same time. This instance can be defined by the vector {“Yes”, “Yes”, “No”, “Full”, “Yes”, “FCFS”}.
5.2.2. Evaluation Results
- Mean (Adjusted) trip duration in hours across all users—this includes driving time (including time searching for available CS), waiting time at charging station and charging time. This metric addresses EV user goals G.01 and G.02 from Section 3.1.1.
- Mean CS utilization—number of hours a CS was in use on average in the simulated period (24 h). This metric addresses charging providers’ goal G.03 from Section 3.1.1.
- Sensitivity analysis experiment where we evaluated all scenarios with 10 different samples of driver origin destination pairs to test sensitivity of our results to geographical changes in demand. The sensitivity analysis suggest that the relative results in Figure 9a,b are preserved when the demand is sampled differently.
- Baseline experiment where we set all CS capacity to infinity to create a baseline for our main results. For comparison with the main experiment, in the baseline, the adjusted trip duration of naive driver is 12 min (0.2 h) longer than that of the prudent driver.
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
BC | business cases |
CS | charging station |
CSO | charging station operator |
DSO | distribution system operator |
EMAID | electric mobility account identifier |
EMSA | e-mobility system architecture |
EMSP | e-mobility service provider |
EV | electric vehicle |
EVSEID | electric vehicle supply equipment identifier |
FCFS | first come first served |
G | goal |
HLUC | high level use case |
HTTP | hypertext transfer protocol |
ICT | information and communication technologies |
IEC | international electrotechnical commission |
IP | internet protocol |
OCN | open charging network |
OCPI | open charge point interface |
OCPP | open charge point protocol |
OpenADR | open automated demand response |
OSCP | open smart charging protocol |
PoC | proof-of-concept |
SSL | secure sockets layer |
TCP | transmission control protocol |
Appendix A. Proof-of-Concept for Ad-hoc Reservation Type
- Processor: multi-core CPU with 4 cores
- Memory: 24 GB RAM
- Storage: 100 GB hard disk
- Network: 100 Mbps
- Operating system: Ubuntu Server 16.04
Appendix A.1. Front-End
Appendix A.2. Back-End
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Design Parameter | Design Options | |||||
---|---|---|---|---|---|---|
Enforceability Level of charging certainty | No | Yes | ||||
Planning Specified start and end times | No | Yes | ||||
Fee Costs incurring from reservations | No | Fixed | Flexible | |||
Data Availability Availability of relevant information | No | Limited | Full | |||
Roaming Reservation across multiple operators | No | Yes | ||||
Scheduling Order in which reservations are processed | Policy | Priority | Auction |
Criteria | Guaranteed Ad-Hoc | Uncertain Planned | Guaranteed Planned |
---|---|---|---|
Enforceability | 1 | 0 | 1 |
Planning | 0 | 1 | 1 |
Fee | 0 | 0 | 0 |
Data Availability | 0 | 1 | 1 |
Roaming | 0 | 0 | 0 |
Scheduling | 0 | 1 | 1 |
Sum | 1 | 3 | 4 |
No Reservations | Ad-Hoc Reservations | Planned Reservations | |
---|---|---|---|
Naive driver | ✓ | ✓ | X |
Prudent driver | ✓ | ✓ | ✓ |
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Basmadjian, R.; Kirpes, B.; Mrkos, J.; Cuchý, M. A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle Charging. Smart Cities 2020, 3, 1405-1427. https://doi.org/10.3390/smartcities3040067
Basmadjian R, Kirpes B, Mrkos J, Cuchý M. A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle Charging. Smart Cities. 2020; 3(4):1405-1427. https://doi.org/10.3390/smartcities3040067
Chicago/Turabian StyleBasmadjian, Robert, Benedikt Kirpes, Jan Mrkos, and Marek Cuchý. 2020. "A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle Charging" Smart Cities 3, no. 4: 1405-1427. https://doi.org/10.3390/smartcities3040067
APA StyleBasmadjian, R., Kirpes, B., Mrkos, J., & Cuchý, M. (2020). A Reference Architecture for Interoperable Reservation Systems in Electric Vehicle Charging. Smart Cities, 3(4), 1405-1427. https://doi.org/10.3390/smartcities3040067