Your search keyword '"Lundahl, Jenny"' showing total 17 results

1. An approach to link technical safety and policy aspects for system innovation in transport – The case of automated trucks

Author

Sobiech, Cilli, Berglund, Pia, Lundahl, Jenny, and Skoglund, Martin

Published

2023

2. Steering the Future: An Overview of Current and Upcoming Regulations in Automated Driving : Version 0.5

Author

Lundahl, Jenny and Lundahl, Jenny

Abstract

This report provides an overview of current and upcoming legal frameworks and instruments relevant for automated vehicles (AV) and automated driving (AD). It is the first version of this overview, which will be updated every six months as long as the project ‘Network AD regulation’ runs. Next version of the overview can be expected around June 2024. In this version, legislation as of December 2023 has been considered. Laws and regulations play a vital role in the safe and efficient integration of AVs into our transportation system. They can ensure that we maximise the benefits of the new technology while minimising the downside risks and help to build public trust in the technology. Vehicles are sold on an international market and much of the traffic goes across national borders. Therefore, harmonised rules are needed, at least to some extent. A regulatory development around AD is ongoing at international level and regional level within Europe, and this has already resulted in some new regulations. More will come within the next few years. Knowledge of international and EU regulations as well as ongoing and planned regulatory initiatives that affect the development and use of AVs is important for actors in the AV space to follow. The shift towards AD is disruptive and complex, not least from a regulatory perspective. AVs need partly different requirements than previous vehicles, necessitating the development of new vehicle regulations and traffic rules. AVs must be able to interact safely with other road users (not least unprotected road users) in various traffic situations and driving conditions; anticipate and detect risks and drive with a margin of safety to prevent accidents and injuries; and follow traffic rules. (It is even likely that some traffic rules will have to be written differently than today.) ‘Vehicle regulations’ set requirements for how the vehicles should be designed and function, while ‘traffic rules’ set requirements for how road users should be, Sweden has 17 strategic innovation programmes funded by the Swedish innovation agency Vinnova, Formas (a research council for sustainable development) and the Swedish Energy Agency.

Published

2024

3. Navigating the Future: Enhancing E-Scooter Traffic Management through Governance and Regulation

Author

Müller, Jan-Hendrik, Andersson, Kristina, Fjällström, Anna, Lundahl, Jenny, Müller, Jan-Hendrik, Andersson, Kristina, Fjällström, Anna, and Lundahl, Jenny

Abstract

The GeoSence project, which is part of the Joint Programme Initiative (JPI) Urban Europe, aims to provide an overview of the current state of the art and showcase practical applications of geofencing. The project partners come from Germany, Norway, Sweden, and the UK and is funded by the European Union's Horizon 2020 programme under the ERA-NET Cofound Urban Accessibility and Connectivity. Geofencing is defined as a virtual boundary in a specific geographical location, either fixed or dynamic. The GeoSence project focuses on improving urban transport by using geofencing methods for traffic planning and management. In this report, we examine the policies that support these solutions, while also identifying barriers and opportunities for smarter regulation. Our research focuses primarily on Munich, looking at issues such as parking, restricted areas, and data collection from e-scooter operators. Many European cities are struggling with problems associated with e-scooters, such as dangerous driving and inappropriate parking. In Munich, geofencing technology has been tested as a solution to address these issues and improve road safety, particularly for pedestrians. The city's main objective was to improve road safety for all road users, especially pedestrians. By reducing inappropriate parking, the city also expected to increase public acceptance of e-scooters. As a first step in dealing with this new form of mobility, the city's initial response included the creation of 30 dedicated parking zones in 2020 and 2021 and a voluntary commitment with mobility service providers to regulate this new form of mobility. By joining the GeoSence project, the city wanted to explore geofencing as a solution to the persistent road safety problems caused mainly by poorly parked e-scooters. With GeoSence, Munich was able to monitor and optimise the use of parking zones, improve parking and road safety, and prevent drunk driving. To define the case studies, the city collected data from e

Published

2024

4. Klimatanpassning av samhällsviktig verksamhet – juridiska utmaningar

Author

Lundahl, Jenny and Lundahl, Jenny

Abstract

Climate adaptation of vital societal functions – a deep dive into the legal issues The climate is changing. This can lead to more frequent extreme weather events which can cause major damages in cities. Especially in larger cities, the climate related damages can go far beyond individual homeowners, as e.g. flooding can impair important societal functions. Today, many cities face the need to implement effective climate adaptation measures. But it is neither possible nor economically justifiable to secure all infrastructure in our cities against all types of climate-related risks. Cities need to prioritize their measures. They may be faced with, for example, the choice of investing in extensive and costly redevelopments or take smaller measures to only protect vital societal functions. Careful consideration of other interests, such as accessibility, is also required. There are organizational, technical, and legal challenges. The roles and responsibilities for various private and public entities, regarding climate adaptation measures, are not entirely clear. In the project “Multifunctional urban climate adaptation in collaboration” (Multifunktionell urban klimatanpassning i samverkan, MuKlis), financed by Vinnova, we explore the conditions for implementing efficient and sustainable climate adaptation of the built urban environment. The focus is on reducing vulnerability in case of cloudburst and heat waves with measures that also create other social, economic, and environmental benefits. In the project, we also explore legal challenges and possibilities for climate adaptation of vital societal functions and critical infrastructure, with a specific focus on the following questions: • If it is legally possible for a public or private actor to protect vital societal functions and critical infrastructure, even if it means an impairment for other actors in the area. • If it is legally possible for local, regional, or national government to demand that a public or private a, Denna rapport är ett resultat av ett arbete som utförts i projektet ”Multifunktionell klimat-anpassning i samverkan” (MuKlis), finansierat av Vinnova (dnr 2021-02465). Projektet har handlat om att skapa förutsättningar för en effektiv och hållbar klimatanpassning i urban miljö.

Published

2024

5. Framtidens trafikregler – Hur når vi dit?

Author

Lundahl, Jenny, Sobiech, Cilli, Thidevall, Niklas, Lundahl, Jenny, Sobiech, Cilli, and Thidevall, Niklas

Abstract

The traffic regulations of tomorrow Traffic regulations are traditionally analogue and paper-oriented. In the future, they need to be able to be interpreted by machines. How can we ensure exchange of reliable data on traffic regulations to support technological innovation such as advanced driver assist and autonomous driving technologies? In this report, we share our knowledge on digital traffic rules – what it is, why it matters and how we get there. The transport sector is becoming increasingly connected, digitalized, and automated. The development is taking place at a rapid pace and has the potential to improve the transport system in several areas (safety, efficiency, environmental impact and accessibility). To meet this development, we need to move towards a more digitalized road infrastructure. A digital representation of the road network is becoming increasingly important. One part of this is digital and machine-readable traffic rules. In a digital world we need data on traffic rules (what applies where). Road users, citizens, companies, and other actors in our society would benefit from such data (they get access to more and clearer regulations). Data on traffic rules also provides completely new opportunities, for example more dynamic traffic regulations, which can further contribute to positive effects for the transport system and for society. It is also a necessity for the implementa-tion of autonomous driving on public roads, since automated vehicles will need a reliable digital infrastructure. Drive Sweden Policy Lab (DSPL) targets specific cases in projects of the strategic innovation program Drive Sweden. The purpose is to explore how technology and service development relate to existing laws and regulations for new mobility services that are being developed, and to identify and overcome bottlenecks. DSPL was initiated in 2019 to support technology development projects within Drive Sweden’s portfolio that had encountered regulatory challenges. New cas, Drive Sweden är ett av 17 strategiska innovationsprogram (SIP). De strategiska innovationsprogrammen finansieras via Verket för innovationssystem (Vinnova), Forskningsrådet för miljö, areella näringar och samhällsbyggande (Formas) och Statens energimyndighet (Energimyndigheten)., Framtidens trafikregler

Published

2023

6. RISE Policylabb – de första fem åren

Author

Andersson, Kristina, Burden, Håkan, Carlgren, Lisa, Lundahl, Jenny, Schnurr, Maria, Sobiech, Cilli, Stenberg, Susanne, Thidevall, Niklas, Andersson, Kristina, Burden, Håkan, Carlgren, Lisa, Lundahl, Jenny, Schnurr, Maria, Sobiech, Cilli, Stenberg, Susanne, and Thidevall, Niklas

Abstract

In this report, we have compiled our learnings and experiences of working with Policy Lab. Policy Labs have come about as an answer to the question "Can you work with policy and regulatory development in a better way than today?". Our answer to the question is a yes. Our hope with the report is that others will become interested and start their own Policy Lab. Abroad, there are many Policy Labs, but in Sweden there are only a few, which is why we believe there is room for more. There is not a given way to work with Policy Labs once and for all, but each Policy Lab is unique based on its context. Sweden's innovation agency Vinnova defines Policy Labs as follows: "Policy Labs can be explained as a group of actors with different competencies who want to develop a regulatory framework. In the Policy Lab, they use a set of user-centric methods and competencies to test, experiment, and learn in policy development."1 In our Policy Lab, we have worked in various research projects to: 1. analyse challenges/problems that arise between innovations, technology, market, and regulations, 2. develop one or more workable solutions and 3. interact with relevant actors to determine the next steps. What distinguishes our Policy Lab is that we never “own” the issue or solution. We must therefore always work with other actors who can take the results further. Our goal is to enable and skill people. This means that for us it is important to work concretely with real problems and needs owners and preferably test different solutions. We focus on the here and now perspective and not on what the future will look like in 10 years. It is about taking the next step forward towards the future, not creating the best rule, but instead creating the next rule. We also work consistently agile and use design as a method for problem solving. This means that the way we organize our work in the Policy Lab is circular and not linear. When it comes to using design as a method for problem solving, we use th

Published

2023

7. Safety Case for Autonomous Trucks (SCAT)

Author

Sobiech, Cilli, Berglund, Pia, Bergman, Mats, Johansson, Viktor, Lundahl, Jenny, Nylander, Tomas, Skoglund, Martin, Strandberg, Ted, Sobiech, Cilli, Berglund, Pia, Bergman, Mats, Johansson, Viktor, Lundahl, Jenny, Nylander, Tomas, Skoglund, Martin, and Strandberg, Ted

Abstract

To aim for market introduction and sustainability of automated vehicles requires technology innovation towards safe products and policy innovation to enable testing on open roads and type approvals. Further, it needs an enabling infrastructure to provide reliable connectivity, business models and increased public acceptance of this new technology. The project SCAT – Safety Case for Autonomous Trucks contributed to this transmission by looking at new policy strategies and system tests to prove how to handle vehicles when introducing this new technology safely. Main objective of the project was to investigate more systematically – from a legal and technical perspective – how to safely operate remote controlled vehicles in mixed traffic and with higher velocity. A safety case for the selected traffic environment has been described and explorative tests have been performed at the AstaZero test site in Sweden. This allowed us to investigate limiting parameters and stress testing the system's boundaries under real conditions with higher velocity – before the actual demo will be run. With regards to policy, we addressed which obligations drivers and road users have according to today's regulations and which of those may need to be handled through technological development, but also through adaptation of legislation in terms of new roles, tasks, and liability when a vehicle is driven automatically. We looked also at if and how these issues are treated in national and international legislation, in Sweden, France and the USA. What we learned from exploring the safety case contributes to practical improvement, theory building and recommendations on how to safely operate the vehicles. Together the partners have developed an approach to advanced argumentation for safety. In our approach, we combined policy lab methodology and an investigation of the technical safety aspects that helped to identify gaps and tests for improved safety. The approach provides step-by-step guidance be, Funding: Vinnova, Swedish Energy Agency, Formas.

Published

2023

8. Challenges and opportunities with the EU Taxonomy Regulation– with focus on chemical safety and usage in complex products

Author

Andersson, Kristina, Hellström, Anna-Karin, Lundahl, Jenny, Andersson, Kristina, Hellström, Anna-Karin, and Lundahl, Jenny

Abstract

The use of Policy Lab processes has been growing in Sweden and other countries to accelerate the adaptation of regulations to emerging technologies. Policy Lab facilitates active collaboration between relevant authorities, companies, and stakeholders through interactive and iterative methods based on Design Thinking principles. This approach bridges the gap between the legislative domain responsible for developing regulatory frameworks and the innovative companies that create solutions for emerging markets using new technologies and opportunities. In our study, we applied Policy Lab processes to the EU Taxonomy Regulation to identify challenges and opportunities related to chemical safety and usage for manufacturers of complex products. The EU Taxonomy Regulation, along with its delegated acts, represent a serious effort to establish standardized sustainability reporting within EU. However, it is still in its early stages and lacks maturity. Moreover, certain ambiguities within the regulation currently prevent a comprehensive comparison of companies due to the development of other legislations. Addressing these gaps depends on the future development of, for example, REACH. Our conclusion is that the EU Taxonomy Regulation is part of a larger “movement” that reflects the policymakers’ intentions. This intention also includes increased data sharing at a significantly different level compared to current practices. In the long run, the shift will enable authorities to access the data and develop new legislations. Our specific focus was on the objective of pollution prevention and control regarding the use and presence of hazardous substances listed in Appendix C of the EU Taxonomy Regulation. According to Appendix C, activities must not lead to the manufacture, placing on the market or use of listed substances, whether on their own, in mixture or in articles. Regarding listed substances, reference is made to existing EU legislation that regulates hazardous substances wi

Published

2023

9. Geostängslade BK4-transporter vid bropassager och på tjälade vägar

Author

Andersson, Kristina, Noreland, Daniel, Lundahl, Jenny, Eriksson, Anna, Andersson, Kristina, Noreland, Daniel, Lundahl, Jenny, and Eriksson, Anna

Abstract

Geofenced heavy trucks to protect bridges at crossings allowing higher weight on frozen roads Winter is our friend. When the road body is deep frozen it can handle more weight than during the rest of the year. However, the bridges are not affected by the cold weather, and they are therefore still vulnerable to increased loads. How can we allow increased loads on frozen roads while ensuring protection of the bridges? In this report, we share our insights from a project with the idea of using geofencing to protect the bridges. The geofencing technology ensures that the truck drives at a lower speed over the bridge and the bridge can withstand loads up to 74 tons since decreased speed reduces dynamic loads. If the road keeper can get guarantees that all heavy trucks drive at a low speed over the bridge, heavier traffic can be accommodated. This technology would of course also be beneficial to use across bridges in Europe regardless of the climate. ' The project “Frozen roads and 74 tons”, paid by the Swedish Transport Administration, consisted of three parts. One part was a pilot study during winter 22/23 demonstrating trucks from AB Volvo and Scania loaded with 74 tons using geofencing when the trucks passed over weak bridges. A speed limit, i.e. 50 km/h, was imposed in a zone around each bridge, whose coordinates were stored in the digital map accessible through the trucks’ Fleet Management System. Two different geofencing technologies were tested: on the one hand Scania’s system with “active” geofencing, where the truck was programmed to maintain the allowed speed over the bridge and calculated and implemented this itself (the driver could, however, override this by pushing the gas pedal to the floor); on the other hand AB Volvo’s system with “passive” geofencing, where the driver received a warning message when approaching the zone and would then slow down if necessary. The drivers were interviewed before and after the pilot about their experience. The results from

Published

2023

10. Safe to circulate : public report

Author

Gutkin, Renaud, Wirje, Anders, Nilsson-Lindén, Hanna, Brunklaus, Birgit, Pashami, Sepideh, Lundahl, Jenny, Essvik, Krister, Enebog, Emma, Jonasson, Christian, Andersson, Oscar, Gutkin, Renaud, Wirje, Anders, Nilsson-Lindén, Hanna, Brunklaus, Birgit, Pashami, Sepideh, Lundahl, Jenny, Essvik, Krister, Enebog, Emma, Jonasson, Christian, and Andersson, Oscar

Abstract

Project within FFI: Accelerate the transition to sustainable road transport

Published

2023

11. Den cirkulära bilen (förstudie)

Author

Brunklaus, Birgit, Diener, Derek, Enebog, Emma, Hautajärvi Stenmark, Heidi, Lundahl, Jenny, Matteoni, Marina, Nyström, Thomas, Nilsson-Lindén, Hanna, Renström, Sara, Brunklaus, Birgit, Diener, Derek, Enebog, Emma, Hautajärvi Stenmark, Heidi, Lundahl, Jenny, Matteoni, Marina, Nyström, Thomas, Nilsson-Lindén, Hanna, and Renström, Sara

Abstract

Syftet med förstudien Den cirkulära bilen var att börja bygga konkreta visioner som möjliggör att Sverige har en cirkulärt anpassad bilflotta med fossilfria och klimatneutrala transporter år 2045 och att bygga en solid bas för ett steg 2-projekt, som i sin tur kommer att ge stöd och kapacitet för aktörer att accelerera den cirkulära bilvärdekedjan. Projektet har samlat 13 parter från hela värdekedjan och gemensamt lagt grunden till vidare arbete i ett fortsättningsprojekt – en ansökan som genererat intresse från ett stort antal parter både befintliga och nytillkommande. Inom studien har startmöten och workshops genomförts där parter samlats digitalt och frågeställningar sonderats. Intervjuer har genomförts med parter där möjligheter och utmaningar med omställningen diskuterats. Studiebesök har genomförts där kunskapsdelning skett och samverkan möjliggjorts. Fysisk workshop har genomförts med samtliga parter. Här tittade man gemensamt på trender och möjliga framtidsscenarios genom hela systemet. Detta gav en bra grund för det vidare arbetet med steg 2. Förstudien har genererat stort intresse från aktörer i hela värdekedjan, skapat nya kontakter och möjligheter till samverkan och blivit uppstarten på en gemensam kunskapsresa för verklig förändring. Studien har initierat arbete brett i värdekedjan kopplat till gemensamma frågeställningar samt framtidsspaningar, vilket möjliggör gemensamt arbete för bred omställning och tydliggjort behovet av åtgärder som förflyttar hela systemet. Detta ses som en god grund för ett steg 2 projekt med förutsättningar för att förverkliga den cirkulära bilvärdekedjan.

Published

2023

12. Elsparkcyklar från ett policyperspektiv

Author

Lundahl, Jenny, Stenberg, Susanne, Faxer, Anne, Lundahl, Jenny, Stenberg, Susanne, and Faxer, Anne

Abstract

Elsparkcyklar har potential att kunna bidra till positiva effekter i samhället. Men med friflytande elsparkcyklar följer också nya utmaningar. En del av dessa är relaterade till regelverk och policy.

Published

2023

13. How can e-scooter better contribute to a sustainable transport system?

Author

Sprei, Frances, Kazemzadeh, Khashayar, Faxer, Anne, Einarson Lindvall, Elin, Lundahl, Jenny, Rosell, Joakim, Melnyk, Kateryna, Holmgren, Kristina, Habibi, Shiva, Stenberg, Susanne, Pettersson, Stefan, Wedlin, Johan, Engdahl, Henrik, Sprei, Frances, Kazemzadeh, Khashayar, Faxer, Anne, Einarson Lindvall, Elin, Lundahl, Jenny, Rosell, Joakim, Melnyk, Kateryna, Holmgren, Kristina, Habibi, Shiva, Stenberg, Susanne, Pettersson, Stefan, Wedlin, Johan, and Engdahl, Henrik

Abstract

The eSPARK project examines the sustainability profile of the popular shared e-scooters through policy analysis, usage data analysis, surveys, and life cycle assessment. Policies and attempts to regulate e-scooters in Swedish and European cities are studied and discussed with stakeholders. The LCA-results suggest that factors such as how e-scooters are collected and distributed, and the total ridden kilometers have significant impact on their environmental impact. The project also suggests different methods that can support cities to predict the geographical area of the e-scooters and offers insights about how e-scooters are used in the cities. Usage data and the surveys show that they are used by active people in areas with a lot of activities, especially restaurants and clubs. Users are likely to have a driving license, to frequently use a car but also to have a monthly pass for public transport. Thus, escooters have a potential to mitigate congestion on roads and public transport but may lead to more traffic on bike infrastructure instead., This project is granted by the Swedish Energy Agency (Dnr 2020-011467)

Published

2023

14. Poster: Säker automatiserad körning från ett policyperspektiv

Author

Lundahl, Jenny and Lundahl, Jenny

Abstract

Automatiserade fordon har på sikt potential att kunna bidra till positiva effekter i samhället. Men med obemannad körning följer också nya utmaningar. En del av dessa är relaterade till regelverk och policy., Funding: Vinnova, Swedish Energy Agency, Formas.

Published

2023

15. Poster: Framtidens ingripanden mot automatiserade fordon

Author

Lundahl, Jenny and Lundahl, Jenny

Abstract

Automatiserade fordon har på sikt potential att kunna bidra till positiva effekter i samhället. Men med obemannad körning följer också nya utmaningar. En viktig utmaning handlar om hur myndigheter ska kunna interagera och kommunicera med dessa fordon., Funding: Vinnova, Swedish Energy Agency, Formas.

Published

2023

16. A systematic multi-layer quantitative method for appropriate location of charging infrastructure

Author

Enerbäck, Oscar, primary, Hagman, Jens, primary, and Lundahl, Jenny, primary

Published

2022

17. Low-frequency wave propagation in an ice-covered Arctic Ocean. Modeling with the spectral element package SPECFEM2D

Author

Lundahl, Jenny Nina Barbro

Subjects

SPECFEM2D, Arctic Ocean, Acoustic wave propagation

Abstract

The significance of sea ice on acoustic wave propagation in the Arctic Ocean is extensively investigated, yet not completely understood. The Arctic sea ice is characterized by ice roughness and ice ridges and to properly model this complex geometry is often a challenge for numerical wave propagation tools. The open-source spectral element package SPECFEM2D is a powerful tool for wave propagation problems in laterally varying domains and can handle coupled fluid-solid domains. In this thesis, SPECFEM2D is used to model low-frequency deep-water wave propagation in an ice-covered Arctic Ocean. Using the axisymmetric version of the software and a point source at the symmetry axis enables simulations with a realistic 3D geometrical spreading at a moderate computational cost. Simulations are performed for a 50 Hz source located at 30 m depth in models with an absorbing bottom at 500 m depth and a propagation range of 4 km. Different models of laterally varying ice-water interfaces are implemented. Ice roughness is modeled with a Gaussian power spectrum with correlation length of 19.1 m and RMS roughness of 0.6 m. Ice ridges of 4.9 and 7.1 m depth are also introduced. Results are compared for a uniform, a linearly increasing and a realistic upwards refracting sound velocity profile in the water. The results suggest that a relatively thin ice layer, whether rough or not, with or without ridges, only impacts Arctic transmission loss at 50 Hz and 30 m depth to a minor extent over shorter ranges. Instead, the sound velocity profile in the water is shown to be the most important parameter controlling acoustic transmission loss at 30 m depth. The wave field in the ice layer itself is much weaker than in the water but is shown to be more impacted by the presence of lateral ice thickness variations.

Published

2022