The Impact of 2020 Low Traffic Neighbourhoods on Fire Service Emergency Response Times, in London, UK

1. Questions

Cities and countries across the world have implemented new active travel infrastructure as part of Covid-19 responses. In London, 72 Low Traffic Neighbourhoods (LTNs) were rapidly rolled out in March-September 2020 under emergency legislation, covering around 300,000 people (4% of London’s population) (Aldred et al. 2021). LTNs use ‘modal filters’ to restrict through motor traffic in residential areas, aiming to discourage driving and to create safer and more pleasant cycling and walking environments.

One concern sometimes raised about LTNs is that, because they restrict motor vehicle access, they may slow response times for emergency services. For LTNs that involve physical barriers, emergency vehicles might have to drive further to reach their destination or stop to unlock a gate. Some LTNs are designed to use camera-enforced closures with emergency vehicle access; however, concerns are still sometimes raised that emergency vehicles could be delayed by increased congestion on surrounding main roads or by having to slow down to navigate the gap between planters.

As LTNs in the UK are a relatively new intervention, the evidence base on such issues is scarce. It currently largely rests on studies of the London Borough of Waltham Forest which introduced several LTNs between 2015 and 2019. A previous study found that the introduction of the Waltham Forest LTNs was not associated with any deterioration in London Fire Brigade emergency response times (Goodman, Laverty, and Aldred 2020). However, it is possible that impacts of 2020 LTNs could be less positive, for example as these lacked the extensive planning and pre-consultation periods used in Waltham Forest. The view of the London Fire Brigade is that “we haven’t yet noticed any impact on our attendance times due to the LTN schemes established in 2020” (London Fire Brigade 2020, 2). Nevertheless, the possibility of negative impacts on emergency response times has been one key controversy surrounding the implementation of the 2020 LTNs, and the focus of much local and some national media coverage.

In this paper we therefore examine the initial impact of London’s 2020 LTNs on London Fire Brigade emergency response times.^[1] We also present analyses of whether any identified impacts differed between LTNs predominantly using physical barriers (e.g. planters) versus using camera enforcement.

2. Methods

We used information from a range of official sources to map all new modal filters^[2] implemented from March-September 2020 in London and still in place at the end of October 2020.^[3] Based on these we manually mapped LTNs and identified the surrounding boundary roads (details in Aldred et al. 2021. See Figure 1).

Figure 1:Map of low traffic neighbourhoods (LTNs) created in London March-September 2020

LTNs are colour-coded according to whether >50% of modal filters were designed to use camera or sign enforcement (LTNs – camera) versus ≥50% of modal filters used physical barriers (LTNs – physical).

We compared October 2020 – February 2021 to the corresponding months in 2018/19 and 2019/20. During this time, the London Fire Brigade responded to 122,440 emergency incidents, of which we excluded 6,822 that lacked response times (e.g. because firefighters were instructed to return to the station before arriving).^[4] Incident coordinate data were available to the nearest metre for 47% of the remaining 115,618 incidents, with the rest having coordinate data to the nearest 100 metres.

Our primary outcomes were the mean response times of the first and second attending engines. When first engine attendance time is >360 seconds, firefighters are asked for the reason for the delay. We examined proportion of delays assigned to different reasons.

We identified whether each incident was A) inside a 2020 LTN or B) <25m from an LTN boundary road. We also identified two overlapping comparison groups: C) incidents outside LTNs (i.e. not in group A or B) but <500m from an LTN, and D) incidents outside LTNs and anywhere else in London. For each of these four groups, we present descriptive analyses comparing October-February 2020/21 to October-February 2018/19+2019/20. We also present significance testing comparing LTN areas (A) and boundary roads (B) to the surrounding areas (C) and the rest of London (D), using interaction terms in linear regression analysis.

After analysing results for the 2020 LTNs as a group, we stratified our analysis according to the LTN’s main modal filter type. We defined this as a binary variable based on whether most modal filters were enforced by cameras and/or signs (i.e. fire engines can pass through) versus physical barriers (i.e. fire crews must unlock a bollard or detour around).^[5]

3. Findings

All areas at both ‘pre’ and ‘post’ time points were comfortably within the London Fire Brigade’s target of first engine average response time <360 seconds, second engine <480 seconds (London Fire Brigade 2020). There was no evidence that the introduction of LTNs was associated with a change in the response time for the first attending engine. The same was true for the second attending engine (Table 1). This lack of any impact applied both inside LTNs and on boundary roads – we did not replicate the slight improvement on boundary roads observed in Waltham Forest (Goodman, Laverty, and Aldred 2020).

This lack of impact on response times was also observed when stratifying by Central/Inner/Outer London status (see Supplemental Information), and when stratifying by whether the LTN predominately used physical or camera-enforced modal filters (see Table 2).

The proportion of delayed first engines (i.e. taking >360 seconds to arrive) decreased somewhat in all area types (e.g. from 21% to 18% inside LTNs, from 28% to 25% in the rest of London: see Figure 2). In all areas, but particularly inside LTNs, there was an increase in the proportion of incidents coded as ‘delayed due to traffic calming’ (from 1.2% to 3.4% inside LTN areas, from 1.6% to 2.1% in the rest of London). This was, however, more than offset by a decrease in the proportion of incidents coded as delayed for other reasons, particularly ‘delayed by traffic, roadworks etc’. There was a larger increase in the proportion of incidents coded as ‘delayed due to traffic calming’ in LTNs predominantly using physical barriers (from 1.1% to 4.0%) than in LTNs predominantly using camera-enforced filters (from 1.3% to 2.9%: see Supplemental Information). Yet in both LTN sub-types, the overall proportion of delays fell two to three percentage points. These findings are in line with previous evidence that LTN introduction does not increase delays overall, but that while LTNs are novel the perception of delay may exist among some crews (Goodman, Laverty, and Aldred 2020). The present findings indicate this effect is particularly marked where most modal filters involve physical barriers.

Figure 2:Change in proportion of delayed first engines (>360 seconds) and in the composition of causes for those delays, following the introduction of low traffic neighbourhoods.

LTN = low traffic neighbourhood. p-values for pre/post difference in the composition of causes for delay: p<0.001 inside LTNs, p=0.04 on the LTN boundary roads, p<0.001 in the rest of London. See the Supplemental Information for a tabulation, and for these results stratified according to whether the LTN predominantly used physical barriers versus camera-enforced modal filters.

In summary, we have used London-wide data from the London Fire Brigade and found no evidence that the LTNs implemented in London in 2020 adversely affect emergency response times. This includes in LTNs predominantly using physical barriers as modal filters. This substantiates the Fire Brigade’s own view that the 2020 LTNs have not affected response times (London Fire Brigade 2020).

ACKNOWLEDGEMENTS

AL is funded by National Institute of Health Research (NIHR) School for Public Health Research. We are grateful to colleagues at Sustrans for their work in checking identification and classification of LTNs.

CONFLICT OF INTEREST STATEMENT

Some 2020 LTNs were funded by the Department for Transport (DfT) via the Active Travel Fund. AG and RA have been awarded DfT funding to evaluate the Active Travel Fund programme as a whole, although this study does not form part of that work. DfT had no input into this article.