Masters' students and third-year undergraduate engineering majors at the University of Liverpool undertake individual projects in the ENGG660 and ENGG341 modules.  These Researchers selected their projects from an original list of Possible Projects.  This website facilitates collaboration among these projects which are thematically linked to Smarter Mobility Network, a larger research effort at the Institute for Risk and Uncertainty. 

Consultations

We meet every week for updates, discussion, practice presentations, etc., on <<day and hour pending>> in room 604 of Brodie Tower or via Zoom at https://liverpool-ac-uk.zoom.us/j/93404339575?pwd=bnhMSkJMQ0dEOGszV0JJWkY5Z0hndz09 (Meeting ID: 934 0433 9575 "scottgroup"; Passcode: $pS^@y1L).  We use https://www.when2meet.com/?30843369-Qqgyc to identify the meeting time.  Meetings and direct consultations are also possible with Scott in his office, over WhatsApp, or via Zoom.   

Independent or collaborative spaces may also be available in Brodie Tower (building entrance at https://w3w.co/rocky.stands.noisy), or on Zoom at https://liverpool-ac-uk.zoom.us/j/93404339575?pwd=bnhMSkJMQ0dEOGszV0JJWkY5Z0hndz09.  

How to use this website

You have your own page under Researchers.  Please edit it. To make a change or add text, just click on the circled pen icon (in the lower, right of the screen). When you're done, you can make your changes public by clicking the blue Publish button and then a second time on the next screen. To see previous versions and compare revisions, select Version History from the More menu (on the right above).  Create placeholders or pose questions in the text that should be expanded or resolved in the text by enclosing them in double angle brackets <<like this>>. Please use such comments to make suggestions or ask questions on the pages of your fellow researchers.  Use the Roman style of addressing and signing your comments, e.g, "<<Scott asks Gang:  how will this work?>>" or "<<Scott asks:  does anyone know about this?>>".  It is easy to include pictures, graphs and equations.  You can upload pictures in PNG, JPG, or TIF files using the Insert/Images menu option while you're editing. Slides in a PowerPoint presentation can be converted to these formats by using the Save As menu option.  To get special characters you can copy é  è  ä  ö  ç  à  α  γ  β  ε  −  ×  ±  ·  •  ®  or symbols from the more complete HTML character table and paste into the text.

Please use this website, rather than sending emails or distributing files to each other directly or severally.  This will better enable us to keep track of our discussions and progress.  Instead of sending e-mails, you should post on the Say page anything you want to broadcast to all collaborators.  This will allow us to maintain a record of our discussions.  You can edit things you previously posted.  You can attach any files you want everyone to be able to access to the bottom of your researcher page.  You can also add comments and attach files to the bottom of any page. 

Keep in mind that all your colleagues can see everything you post on this site.  Google also automatically keeps a record of all the changes you make to the site, which everyone can also see.

Don't feel that you have to post about every little thing.  It's usually better if you go ahead and directly add new material to your page or make a change to a page, rather than merely talking about it.  If something should be fixed, go ahead and fix it by editing the page directly.  If appropriate, you can highlight the change in blue to indicate an uncontroversial change, or in red to indicate changes you want the collaborators to be sure to notice.  Other colours, including background colours, may also be used.

What the overarching project will do

The Smarter Mobility Network will develop a mobility decision support system developed and maintained by open-source co-creation (like Wikipedia) to advise both regional planners and individual travellers. The system employs stochastic optimisation (stochastic programming) to identify optimal modes, schedules and routes for travel from pre-computed risk maps that account for various costs of travel including

The system facilitates distributed optimal decision making by leveraging stochastic optimisation techniques and blockchain accounting with strong encryption to protect personal privacy. The risk maps are created by both generic models that are developed for worldwide use and local models developed for particular regions using local expertise and regional data. Individual travellers making use of the smart phone app will create a feedback stream of data relevant for the decision engine and transportation science generally. Encouraged under a citizen science program, data streams from hospitals, insurers, police, government bodies, and other contributors will also inform the decision engine about local conditions. Network research partners will also develop local data sets and data streams, and particularly the local risk models that take account of local laws, customs, conventions within each country or region. Everyone can contribute to the data sets and models used to create risk maps, so the result is a truly co-created system.

Management and regional planning. The decision engine can be used by regional planners and transportation engineers to identify problem spots--and optimal remedies--in traffic networks of high injury risks, congestion-related delays, and network imbalances and siting suboptimalities. These uses range from planning future infrastructural development, policy making for regulation and incentivisations, managing daily or seasonal traffic flows, and handling emergency evacuations. The use of the decision engine for management and planning will be the primary means by which the research and development of the Network makes its greatest impact on reducing  fatalities and injuries and economic and environmental costs suffered by travellers. This use represents local empowerment of governments and regional authorities, policy makers, and transportation scientists and engineers to improve mobility systems for citizens.

Personal trip planning with smart phone app. The stored maps and map products can be accessed and individual trips can be planned and optimised via a cloud-based smart-phone application. Personally optimal decisions are identified by applying individualised decision rules that reflect the personal attitudes and past choices of a traveller. Different people have different requirements and different values. They have different "risk appetites" that depend on their personalities and goals. In general, the tolerable risks and costs are different for commuters, shoppers, students, truckers, delivery persons, and leisurists. In fact, a single person has different requirements and values over time depending on the purpose of a trip. The smart phone app has several features that make it markedly more useful than many currently available trip planning software tools, but this app is primarily important because it creates a stream of relevant local data on which the decision support systems depends. It is itself part of the citizen-science collective effort. The system collects mobility demand and use data from the smart-phone application and feeds the information back to validate and enrich the stochastic models used in the decision support system.

Protections. The system and app do not archive personal information about individual travellers. It uses intervalisation and compartmentalisation for strong anonymisation of its data which constrains statistical risks of re-identification or other disclosure of personal information about users and other travellers. The personal information necessary for planning individual trips is encrypted in blockchain ledgers that allow brokerage between the smart-phone app and the decision system.  Like Wikipedia, the system also incorporates mechanisms to detect, minimize and mitigate other improper uses by individuals or governments such as vandalism, rumour-mongering, advertising, espionage, and warfare.

Distributed decision making. The decision engine addresses two very different problems.  The first problem is finding an optimal trip (route, mode of carriage, schedule, cargo, etc.) from among all possible trips given the personal risk and uncertainty preferences of a traveller and the constraints governing the trip and the traveller (accessible vehicles, monetary and non-monetary costs, routine or emergency purpose of the trip, local laws, etc.). This first problem is relatively simple compared to the second problem which addresses decisions by regional planners about possible governmental infrastructural investments, laws and regulations, tax policy, incentivisation programs, and other governmental and social policies and acts available to local, regional or national governments. The decision engine should be helpful to regional planners in identifying optimal decisions within a circumscribed class--or at least ranking alternative actions--in terms of the aggregate costs to government, travellers, other citizens, and other stakeholders.