Analyse the mobility situation
Step 3 of 12 Preparation & Analysis
With the working structures in place and the planning framework set, Step 3 is where the plan finally meets reality. It builds the **evidence base** the rest of the SUMP will stand on: how people actually move today, where access to everyday life falls short, who is most affected by those gaps, and what the genuine opportunities are. Just as importantly, it fixes the **baseline**, the measured starting point against which the finished plan will later be judged. A plan is only ever as good as the diagnosis underneath it, and a weak or borrowed diagnosis produces a weak or borrowed plan.
What standard analysis misses in the periphery
Conventional mobility analysis is tuned to the dense city core, where the headline problem is congestion and the natural metrics are traffic volumes, journey speeds and modal split at the cordon. Carried unchanged into the outskirts, that lens measures the wrong thing. In low- and mid-density peripheries the real issue is not that movement is slow but that **so much of daily life can only be reached by car at all**: whether a resident can get to groceries, a doctor, a school or a green space on foot, by bike or by public transport. DREAMS reframes the analysis around **proximity and accessibility** rather than traffic flow, and that shift changes both what you measure and what you count as a problem in the first place.
The DREAMS benchmarking work (Deliverable 2.3) shows why this matters empirically. Drawing on national household travel surveys across the six study regions, it found that accessibility in the outskirts is generally worse than in the urban core — Budapest's periphery had the lowest accessibility for both work and shopping trips, while Munich was the notable exception, with shopping and leisure access actually improving in its suburbs. Above all, the analysis found a high degree of **car dependency for everyday trips in the suburbs, and especially for shopping**, which is exactly the kind of routine, frequent journey a 15-minute neighbourhood is meant to bring within reach. Diagnosing that car-dependency honestly, trip purpose by trip purpose, is the work of this step.
How DREAMS measures accessibility
The platform's **DREAMS Accessibility Tool (DAT)**, described in **Deliverable 3.1**, gives practitioners a way to map this directly. Rather than counting cars, it asks of every location a simpler question: what share of the amenities people actually care about — groceries, pharmacies, schools, cafés, parks and the rest — can be reached within an acceptable walk? It answers that question two different ways, and the **gap between the two answers** is the single most useful insight the tool produces.
The first is a **normative**, textbook "15-minute city" view: every amenity is weighted equally, and being able to reach just one of each within a 15-minute walk counts as success. The second is a **perceived** view, where the weights, the number of each amenity people want nearby, and the walking times they will genuinely accept are all drawn from the DREAMS resident survey across the six living labs. The normative view tells you what an abstract standard says about your area; the perceived view tells you whether residents would actually experience it as well served. They rarely agree.
What the living labs revealed
Measured against the normative standard, the labs look reasonably healthy — multi-amenity compliance ranged from **0.77 in Évry-Courcouronnes** (Paris), **0.76 in Liesing** (Vienna) and **0.75 in Haren & Neder-Over-Heembeek** (Brussels), down through **0.71 in Overvecht** (Utrecht) and **0.64 in Geretsried** (Munich) to **0.61 in Rákosmente** (Budapest). On paper, most of these places already look like passable 15-minute neighbourhoods.
Apply residents' real preferences, though, and accessibility **falls in every single lab** — by around **0.21 on average**. The drop is sharpest precisely where people most want choice and proximity: in Brussels, compliance for **parents** fell from 0.75 to **0.46**; in Munich, **older adults** dropped to **0.36**; in Budapest, **working-age adults** fell from 0.61 to **0.36**; in Utrecht, **low-income residents** to **0.55**. Across almost every lab the single biggest driver of the gap is **access to grocery stores** — the amenity people value most highly, need most often, and find most consistently under-supplied within walking distance. This is the quantified counterpart to the car-dependency-for-shopping finding from the benchmarking work: the trips people are forced to drive for are, very often, the grocery runs.
DREAMS also looked beneath the averages. A persona analysis of the survey data (Deliverable 4.2) found that accessibility needs do not map neatly onto age or income — some profiles, such as families with children or older people ageing in place, follow clear life-course logics, while others, built around daily convenience or social life, cut straight across demographic lines and coexist within the same neighbourhood. The behavioural choice experiments reinforced the point: public transport remained the most stable and attractive option everywhere, with shared and micromobility services working as **complements rather than universal substitutes**, their usefulness depending heavily on trip purpose and local context. The practical message for your analysis is that a single neighbourhood average will hide the groups your plan most needs to serve.
Three lessons follow directly, and they shape every later step of the SUMP:
- One of each is not enough. Residents value having *alternatives* — two or three groceries, not one — so any target framed as "a single amenity within 15 minutes" will systematically overstate how well an area actually works.
- Most peripheries have a good cluster and an underserved edge. Every lab contained at least one well-served core (compliance above 80%), but more peripheral pockets stayed poorly served. The equity gap is spatial, so a single headline figure for the whole area will mask it.
- Walking alone will not close the gap. Deliverable 3.1 concludes that bringing in the **bicycle, shared micromobility and public transport** is essential in the outskirts — both to provide a basic level of access and to widen the real options residents have.
Doing it in your own area
The sequence for this step is the same whether you use the DREAMS tools or your own data. Start by assembling what already exists — household travel surveys, census and land-use data, public transport service data, and an OpenStreetMap-based amenity inventory — and map your area's **normative** accessibility to see where the obvious cold spots are. Then gather the **perceived** side through a resident survey, so you learn not just what is reachable but what residents need, how many of each amenity they want, and how far they will really walk. Compare the two, break the results down by the population groups your framework singled out in Step 2, and write the findings up as an explicit, dated **baseline**. Resist the temptation to analyse everything at once: a focused diagnosis of the trips and groups that matter most will serve the plan far better than an exhaustive one that no one finishes.
Tools for this step
ResiMob: the resident mobility survey instrument used to capture local travel behaviour and amenity preferences.
Go deeper
The idea that *perceived* accessibility differs from the calculated kind is shared by the sister DUT project AccessCity4All, which combines accessibility modelling with walk-along interviews and participatory mapping across neighbourhoods from central to outskirt — a useful complement to the DREAMS survey-based approach. For practical guidance on gathering the data, especially on walking and cycling, see Module 3: Data for active modes (Baltic Sea Region Competence Centre on SUMP).