Towards a simplified performance-linked value for money model as a reference point for bus contract payments
The burgeoning commitment to contracting the delivery of bus services through competitive tendering or negotiated performance-based contracts has been accompanied by as many contract payments schemes as there are contracts. We are now well placed to design a simplified performance-linked payment (SPLP) model that can be used as a reference point to ensure value for money, given the accumulation of experiences throughout the world which have revealed substantive common elements in contracts. Whether the payment to the operator is framed as a payment per passenger or as a payment per service kilometre, the SPLP identifies efficient subsidy outcomes that are linked to a proxy indicator of net social benefit per dollar of subsidy. We illustrate how the SPLP model can be applied to obtain the gross (subsidy) cost per passenger (or per passenger km) from measures of gross cost efficiency and network effectiveness. This model can then be used as part of a benchmarking activity to identify reference value of money prospects in respect of passengers per $ subsidy outlay by adjusting for influences not under the control of the service provider. A single framework to identify contract payments to operators, and to assess (i.e., benchmark) operator performance on critical KPIs, is provided by internalising critical key performance indicators (KPIs) in the design of the SPLP. The proposed SPLP model is sufficiently general to be independent of the procurement method (competitive tendered or negotiated, for example) and of the treatment of revenue allocation (net or gross based contracts), with the additional advantage of being able to assess value for money for government.
Impact of design elements on the capacity and speed of Bus Rapid Transit (BRT): the case of a single lane per direction
Despite its booming growth, the BRT industry is still far from reaching maturity. As trial-and-error and empiric techniques were largely used as insights for innovations in design, some BRT systems achieved great successes in terms of performance and became world-class flagships whereas others would be most properly classified as busway systems requiring major improvements. In this paper we explore the performance of a single lane per direction no-overtaking BRT corridor, in terms of capacity and operating speed, by conducting a design of experiments that comprised the simulation of 324 alternative scenarios. In the simulation runs we varied demand levels, boarding and alighting rates, spacing of stations, vehicle loadings, quantity of berths per station, and traffic signal positioning in relation to stations. The qualitative analysis reveals that such a BRT system can achieve a capacity around 15,000 pass/h/dir along its critical section with an operating speed of 20 km/h. Preliminary statistical analysis enabled the estimation of a regression model representing the impact of BRT design elements on the operating speed. Our findings provide useful insights for designers of high-performance BRT corridors.