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It was twenty years ago today: revisiting time-of-day choice in The Netherlands

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  • Significance b.v.
  • Significance b.v.

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Time-of-day (TOD) choice can be considered as a fifth stage in the modelling of transport behaviour, additional to the conventional four stages. Twenty years ago in The Netherlands, a stated preference (SP) study was designed for investigating the choice of time-of-day (departure time) and transport mode. A nested logit time period and mode choice model, largely based on this SP data set, was included as one of the components of The Netherlands national transport model (LMS). A new TOD SP survey has now been developed to obtain up-to-date information for the next re-estimation round of the LMS. The fieldwork was carried out in in 2019, followed by the re-estimation of the nested logit model of period and mode choice on the new SP data. The context for the SP is that of a tour (round trip) carried out by the respondent as car driver or by train, also distinguishing by travel purpose (commuting, business, education and other). This means that we are asking questions both about the outward leg of the tour and the inward leg. Both car drivers and train users are asked to participate in two SP experiments on TOD and mode choice: the first focussing on the trade-off between congestion or crowding and the departure/arrival times; the second also with differentiation in costs between peak and off-peak. Our tentative conclusion is that TOD choice seems to have become (relatively to mode choice) more flexible in the past two decades, in line with the trends towards more flexibility in scheduling activities over the day and a 24 hours economy. Moreover, we now estimate nest coefficients for both car drivers and train users (until now the assumption that had to be made in the LMS was that the nest coefficients for train followed those for car).
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Transportation Research Procedia 49 (2020) 119–129
2352-1465 © 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
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10.1016/j.trpro.2020.09.011
10.1016/j.trpro.2020.09.011 2352-1465
© 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
Peer-review under responsibility of the Association for European Transport
Available online at www.sciencedirect.com
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www.elsevier.com/locate/procedia
2352-1465 © 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
Peer-review under responsibility of the Association for European Transport
47th European Transport Conference 2019, ETC 2019, 9-11 October 2019, Dublin, Ireland
It was twenty years ago today: revisiting time-of-day choice in The
Netherlands
Gerard de Jonga,b*, Marco Kouwenhovena,c, Andrew Dalyb, Sebastiaan Thoena, Matthijs
de Gierd, Frank Hofmane
a Significance, Grote Marktstraat 47, 2511 BH Den Haag, The Netherlands
b Institute for Transport Studies, University of Leeds, University Road 36-40, Leeds LS2 9 JT, UK
c Delft University of Technology, Faculty of Technology, Policy and Management, Jaffalaan 5, 2628 BX Delft, The Netherlands
d Kantar Public, Amsteldijk 166, 1079 LH Amsterdam, The Netherlands
e The Netherlands Ministry of Infrastructure and Water Management, Rijkswaterstaat, WVL, Lange Kleiweg 34, 2288 GK Rijswijk, NL
Abstract
Time-of-day (TOD) choice can be considered as a fifth stage in the modelling of transport behaviour, additional to the conventional
four stages. Twenty years ago in The Netherlands, a stated preference (SP) study was designed for investigating the choice of time-
of-day (departure time) and transport mode. A nested logit time period and mode choice model, largely based on this SP data set,
was included as one of the components of The Netherlands national transport model (LMS). A new TOD SP survey has now been
developed to obtain up-to-date information for the next re-estimation round of the LMS. The fieldwork was carried out in in 2019,
followed by the re-estimation of the nested logit model of period and mode choice on the new SP data. The context for the SP is
that of a tour (round trip) carried out by the respondent as car driver or by train, also distinguishing by travel purpose (commuting,
business, education and other). This means that we are asking questions both about the outward leg of the tour and the inward leg.
Both car drivers and train users are asked to participate in two SP experiments on TOD and mode choice: the first focussing on the
trade-off between congestion or crowding and the departure/arrival times; the second also with differentiation in costs between
peak and off-peak. Our tentative conclusion is that TOD choice seems to have become (relatively to mode choice) more flexible in
the past two decades, in line with the trends towards more flexibility in scheduling activities over the day and a 24 hours economy.
Moreover, we now estimate nest coefficients for both car drivers and train users (until now the assumption that had to be made in
the LMS was that the nest coefficients for train followed those for car).
© 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
Peer-review under responsibility of the Association for European Transport
Keywords: Time-of-day choice ; mode choice ; stated preference survey ; national transport model
* Corresponding author. Tel.:+31-6-53404000.
E-mail address: dejong@significance.nl
Available online at www.sciencedirect.com
ScienceDirect
Transportation Research Procedia 00 (2019) 000000
www.elsevier.com/locate/procedia
2352-1465 © 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
Peer-review under responsibility of the Association for European Transport
47th European Transport Conference 2019, ETC 2019, 9-11 October 2019, Dublin, Ireland
It was twenty years ago today: revisiting time-of-day choice in The
Netherlands
Gerard de Jonga,b*, Marco Kouwenhovena,c, Andrew Dalyb, Sebastiaan Thoena, Matthijs
de Gierd, Frank Hofmane
a Significance, Grote Marktstraat 47, 2511 BH Den Haag, The Netherlands
b Institute for Transport Studies, University of Leeds, University Road 36-40, Leeds LS2 9 JT, UK
c Delft University of Technology, Faculty of Technology, Policy and Management, Jaffalaan 5, 2628 BX Delft, The Netherlands
d Kantar Public, Amsteldijk 166, 1079 LH Amsterdam, The Netherlands
e The Netherlands Ministry of Infrastructure and Water Management, Rijkswaterstaat, WVL, Lange Kleiweg 34, 2288 GK Rijswijk, NL
Abstract
Time-of-day (TOD) choice can be considered as a fifth stage in the modelling of transport behaviour, additional to the conventional
four stages. Twenty years ago in The Netherlands, a stated preference (SP) study was designed for investigating the choice of time-
of-day (departure time) and transport mode. A nested logit time period and mode choice model, largely based on this SP data set,
was included as one of the components of The Netherlands national transport model (LMS). A new TOD SP survey has now been
developed to obtain up-to-date information for the next re-estimation round of the LMS. The fieldwork was carried out in in 2019,
followed by the re-estimation of the nested logit model of period and mode choice on the new SP data. The context for the SP is
that of a tour (round trip) carried out by the respondent as car driver or by train, also distinguishing by travel purpose (commuting,
business, education and other). This means that we are asking questions both about the outward leg of the tour and the inward leg.
Both car drivers and train users are asked to participate in two SP experiments on TOD and mode choice: the first focussing on the
trade-off between congestion or crowding and the departure/arrival times; the second also with differentiation in costs between
peak and off-peak. Our tentative conclusion is that TOD choice seems to have become (relatively to mode choice) more flexible in
the past two decades, in line with the trends towards more flexibility in scheduling activities over the day and a 24 hours economy.
Moreover, we now estimate nest coefficients for both car drivers and train users (until now the assumption that had to be made in
the LMS was that the nest coefficients for train followed those for car).
© 2020 The Authors. Published by ELSEVIER B.V.
This is an open access article under the CC BY-NC-ND license (https://creativecommons.org/licenses/by-nc-nd/4.0)
Peer-review under responsibility of the Association for European Transport
Keywords: Time-of-day choice ; mode choice ; stated preference survey ; national transport model
* Corresponding author. Tel.:+31-6-53404000.
E-mail address: dejong@significance.nl
120 Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129
2 Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000
1. Introduction
Twenty years ago in The Netherlands, a large stated preference (SP) study was designed for investigating
simultaneously the time-of-day (TOD) choice and transport mode choice. Time-of-day choice can be considered as a
fifth stage in the modelling of transport behaviour, additional to the conventional four stages. This is an important
stage to add to a transport model in order to simulate all types of travellers’ responses to increased congestion: will
travellers avoid the congestion by shifting to another travel mode, or by shifting to another departure time, or will
their travel behaviour remain unchanged? Including time-of-day choice is also important when simulating travellers’
responses to a time-varying congestion charge, e.g. a peak charge. Again, the travellers can choose to change their
travel mode, their departure time, or to pay the charge (and possibly benefit from reduced congestion).
The SP-survey was planned in 1999, the design was worked out in 2000 and the data collection took place in 2000-
2001 among more than 1000 car drivers and train users travelling in the extended peak periods. The data were used to
estimate error components models (de Jong et al., 2003) and nested logit models (Hess and Daly, 2007). A time period
choice model, for an important part based on this SP data set and following the latter specification, was included as
one of the components of The Netherlands’ national transport model (LMS). All the other behavioural data that was
used for estimation of the LMS is of a revealed preference (RP) nature. In the nested logit model structure of the LMS,
TOD choice for commuting and non-home-based business trips is positioned below mode choice, implying that TOD
choice is more sensitive to time and cost changes than mode choice. For the other travel purposes, both choices are at
the same level. A key parameter that we need to estimate on the SP TOD data is the nest coefficient between TOD
and mode choice, that influences the relative sensitivities of these choices.
The time-of-day SP questionnaire developed for the Netherlands in 2000 was later also used as a template for a
similar SP survey in the West-Midlands (UK) which served for estimating the PRISM model. Furthermore, a
comparison of various models, based on these two data sets and a TOD SP for London, was undertaken (Hess et al.,
2007a, b), with a focus on finding the most appropriate way of nesting TOD and mode choice. The outcomes of this
work, notably that TOD choice should be at the bottom of the choice hierarchy, were incorporated in WebTAG, the
Department of Transport’s guide to transport appraisal in the UK.
Since the collection of the time-of-day SP data in 2000-2001, the various components of the LMS have been re-
estimated several times on more recent RP data. The TOD SP data however remained the same. The Netherlands
Ministry of Infrastructure and Water Management, Rijkswaterstaat, WVL felt that the 2000-2001 data could no longer
be used for the next re-estimation round of the LMS and that new data had to be collected. Therefore, a new TOD SP
survey was developed to obtain up-to-date information. The fieldwork for this new survey was followed by the re-
estimation of the nested logit model of period and mode choice on the new SP data.
The paper discusses the design of the new SP survey (section 2), the conduct of the survey, the preparatory analysis
of the collected data (section 3) and the estimation results of the nested logit model of period and mode choice on the
new SP data (section 4). In the final section (section 5), we will compare the survey and the estimated model to those
of twenty years ago and discuss the implications of the findings.
2. Survey design
The LMS is a tour-based transport model. A tour is defined as a round trip: a series of trips that begins and end at
the same place, such as the home or work location. It is therefore important for the SP survey to define experiments
in the context of a tour. To increase realism of these experiments, this needs to be a tour that was actually carried out
by the respondent, distinguishing different segments by mode used and travel purpose (commuting, business,
education and other). This in turn implies that we are asking questions both about the outward leg of the tour and the
inward (return) leg. Respondents are only in scope if at least one of these legs is in the period 6.00-10.00 or in the
period 15.00-19.00 (the extended peak periods). The SP alternatives are based on the characteristics of both legs of
the tour as given earlier in the interview by the respondent and reflect the legs of the tour as a whole (tour-based SP).
Also, the LMS refers to a working day, and so should the SP survey. All of this applies to both the 2000 survey and
the new one.
In the SP experiments we try to offer trade-offs between attractive departure times and short travel times (as in the
scheduling model of Vickrey (1969) and Small (1982)), or between attractive departure times and low transport costs.
Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129 121
Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000 3
In the survey carried out in 2000-2001, we had two SP experiments, the first (SP1) without peak pricing, focussing
on congestion in the peaks, and the second (SP2) with peak pricing. For both SP experiments each choice situation
contained four choice alternatives:
The first alternative had departure times close to the observed departure time (the same or a bit earlier/later);
The second alternative had considerably earlier departure times;
The third alternative had considerably later departure times;
The fourth alternative referred to another mode than observed (public transport for car drivers, car for train
users).
In the new survey, we again interview car drivers and train users, carrying out two SP experiments on TOD and
mode choice. As in 2000, SP1 refers to situations with more congestion in the peaks and SP2 refers to situations with
higher transport costs in the peaks. We still present four alternatives per choice situation (on one choice screen), but
the philosophy behind these alternatives is somewhat different than in 2000:
Car drivers:
SP1 with four alternatives (two for road and two for train or other public transport) focussing on the trade-
off between congestion and the departure and arrival times of both legs of the tour;
SP2 with the same four alternatives, but focussing on the trade-off between congestion, car cost
differentiation between peak and off-peak and the departure and arrival times of both legs of the tour;
Train users:
SP1 with four alternatives (two for rail and two for car driver or car passenger) focussing on the trade-off
between the probability of a seat, train frequency and the departure and arrival times of both legs of the tour;
SP2 with the same four alternatives, but focussing on the trade-off between probability of a seat, train
frequency, rail fare differentiation between peak and off-peak and the departure and arrival times of both legs
of the tour;
This setup is comparable to the setup that was used for SP experiments on TOD and route choice carried out
recently in Copenhagen (Lu et al., 2018). We selected this presentation with two car and two public transport
alternatives instead of the one with only a single other mode alternative because of the focus of this study on estimating
the nest coefficient between mode and TOD choice for LMS. The new setup should provide more information on
shifts to other modes and in this respect has a better balance between mode and TOD choice. Furthermore, whereas
in the old survey we had an alternative that kept close to the observed departure time and two that were substantially
earlier and later, we now have two alternatives for the observed mode with departure times that vary over the range
of all possible departure times. We expect that this will provide more preference information and the risk that
respondents in their choice-making just try to justify their observed choice will be avoided or at least reduced.
Also, we want to focus on alternatives that are evenly distributed over the extended peak periods, including
departure and arrival times that fall outside of the possible period with a higher peak cost. More specifically, this
means that a traveller, who currently departs long before the morning peak to avoid the queue, will not see choice
alternatives that depart more than half an hour earlier than observed (and similarly for those that depart long after the
morning peak). This is another deviation (improvement in our view) from the 2000 SP survey. For experiment SP1
we present eight choice situations, and also eight for SP2.
We ask each car driver which form of public transport he/she would use for the tour. If the answer is train or
bus/tram/metro, then we use this mode for the two alternatives with another mode than observed for the tour. Should
the respondent say that no public transport is available, we still offer hypothetical bus alternatives for the third and
fourth alternatives, again because of our focus to get information on the nest coefficient between mode and TOD
choice (and because we cannot present credible costs for walking or cycling).
Train users are asked whether car (as driver) would be available for the tour. In case this is not available (e.g. no
driving licence, household without a car), we use for the third and fourth alternatives car passenger/carpool, where the
traveller pays a contribution toward the travel cost of the tour.
The four alternatives that are presented to the respondents are described in terms of their attribute values, the
attributes being:
Departure time from home (or from work for work-based tours)
122 Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129
4 Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000
Arrival time at the destination
Departure time at the destination
Arrival time at home (or work for work-based tours)
Travel time for the tour (for public transport this includes access and egress)
Duration of stay at the destination (activity time)
Travel cost for the tour, not including the peak charge
Peak charge for car or train (only in SP2)
A simple measure of crowding in public transport: probability of getting a seat
Frequency of the public transport.
In the travel cost, we distinguish several possibilities with regards to the compensation that travellers may receive
from their employers and we take account of the fact that students can travel at a zero or reduced rate depending on
the day and TOD. Respondents were asked to give both their first and second choice from the set of four alternatives.
An example of the choice screens can be seen in Appendix A.
The design tables contain between 23 and 25 design attributes (depending on the experiment) that determine the
values of the attributes mentioned above. These design attributes determine the size of the time shift, whether this
shift applies to the departure or the arrival time, whether this shift applies to the outbound or the return journey, the
amount of congestion/delay during the outbound and during the return journey, the change in the duration of the stay
at the destination, the change in the travel cost, the amount of crowding and the frequency of the public transport
alternative.
The design tables were generated by the Ngene software package (ChoiceMetrics 2018). We used a D-efficient
design. Since it was not possible to find a prior for several of the design attributes, we treated all attributes as dummies
and used dummy codes in Ngene (see Section 7.2.8. in the manual). By using a D-efficient SP design (a technique
that we did not know of in 2000, where the design was adapted from an orthogonal one) we were able to reduce the
required sample size to 900 interviews (500 for car drivers and 400 for train users). Different targets were set by mode
and purpose, because we want to get enough observations for each mode, and enough observations to estimate separate
models by travel purpose.
3. The data
For this survey, respondents were recruited from the NIPObase panel, the natural successor of the NIPO Capibus
that was used for recruitment in 2000-2001. The NIPObase panel acquires its membership by invitation only (as
opposed to panels that advertise to find members). First, a screening among the members was carried out to determine
whether the head of the household or other household members had travelled in the extended peak periods on a
working day and to determine the mode and travel purpose (which were separate strata with their own target numbers
of interviews). After this screening, respondents that were in scope were invited to participate either for the pilot or
the main survey.
The fieldwork took place in the period March - April (pilot) and May June (full survey) 2019. The pilot was
carried out to test the fieldwork procedures and questionnaire and improve the presented attribute levels, and led to
some minor changes for the main survey. A large part of the pilot data could also be used in the main analysis. The
questionnaire was programmed and the respondents accessed it and provided their answers through the internet
(computer-assisted web interviewing, CAWI), either using their PC/laptop (63%), smartphone (35%) or tablet (2%).
In 2000-2001, the internet penetration was much lower and one had to rely on computer-assisted personal (CAPI)
interviews. The NIPObase panel members who participated received a reward, which they could keep for themselves
or donate to a charity.
Table 1 presents the targets for the number of interviews as well as the numbers that were obtained, after filtering
out respondents that always chose the same alternative, completed the interview in a very short time (i.e. within ten
minutes) or had provided or seen clearly incorrect travel times, cost, duration of stay, arrival or departure times. It is
clear from this table that all the targets were met. We aimed for 500 car driver interviews and 400 for train users, and
obtained 593 and 501 interviews respectively (1094 in total). This slightly exceeds the number of interviews we
obtained in 2000-2001 (1051, where the target was 964). The average interview time, after removing the ones below
ten minutes, is 24 minutes.
Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129 123
Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000 5
We checked the composition of the resulting sample in terms of education level, occupation, age and gender,
comparing this to statistics on the Dutch population. We found that there is some overrepresentation of persons with
a higher education and older people. We expect this is caused not so much by the composition of the NIPObase panel
or selective response from it, but a result of our targets which overrepresent commuting and especially business tours.
For the estimation of the discrete choice models this overrepresentation is not problematic (consistent coefficients can
be estimated on samples that are selective in exogenous variables), but in application we need to make sure that we
properly expand to the population (as happens as part of the application within the LMS).
Table 1. The target numbers of interviews and the numbers achieved (pilot plus main survey), after applying filters.
Travel purpose (car) Target Achieved
Travel purpose (train) Target Achieved
Commuting, flexible working hours 95 108
Commuting 150 210
Commuting, non-flexible working
hours
95 97
Business, home-based 85 94
Business 70 83
Business, work-based 65 80
Education 85 109
Other, incl. education
214
Other, excl. education
95
99
Total
593
Total
400
501
We also checked whether there is sufficient trading in the SP responses. We found that the shares of respondents
that change mode in the SP experiments is between 37% and 61% (depending on SP1 and SP2 and on whether we
include the second choice answers or only the first choices). This is a quite reasonable outcome for an SP experiment
with mode choice. The fraction of respondents that always chooses the fastest alternative is 5-7% and it’s 6-8% for
always choosing the cheapest alternative.
4. Model estimation
After this, we re-estimated the nested logit models for mode and TOD choice by purpose from Hess and Daly
(2007). We could have estimated mixed logit models, but these are impractical in the context of the larger LMS.
Estimation and application of mixed logit models requires a large number of random draws and repeated calculations
for each of these. In the LMS, with very many choice alternatives, these mixed logit calculations would take far too
long. The nested logit estimation results by travel purpose, distinguishing commuting, business and other, are in Table
2. This is not necessarily the final use that we will make of the new SP data, since a project to re-estimate the entire
LMS travel demand model has started recently, that will try to estimate joint models for mode, destination and TOD
choice on a combination of RP and SP data, including the new TOD and mode choice SP data. A fall-back option
would be to use in the LMS only the new nesting coefficients from an SP-only model.
What we now do is that, in as far as possible, we use the best model specification from the previous investigation
to estimate an SP-only model. By doing this we can also see which coefficients are not significant this time. Even
though we also asked the respondents to give their second choice, we only use the first choices in estimation, as we
found that the second choices contain considerably more illogical effects and impair the accuracy of estimation. In
2000-2001, we only asked for the first choice, so this selection also makes the data from 2000-2001 and 2019 more
comparable.
Within each of the three purposes, we combine the data for car users and train users, as well as the SP1 and SP2
data in a simultaneous model, but we do estimate a scaling factor for train relative to car and another for SP2 relative
to SP1 to account for the possible difference in unobserved variance between these modes and experiments.
The first block of estimated coefficients in Table 2 refers to the attributes that were shown in the SP experiments
(cost, time, frequency and probability of a seat). These coefficients all have the expected sign, and except for train
cost in the commuting model and car and train cost and frequency for business they are also significant at the 90%
confidence level. It is worth noting that the t-ratios in Table 2 fully correct for the fact that our data are a form of panel
data with multiple observations from the same person. The software used for estimation, Biogeme (Bierlaire, 2013,
124 Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129
6 Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000
2018), routinely produces standard and robust t-ratios for models without mixed-logit effects. For a proper estimation
of the t-ratios in the presence of panel effects, one needs to use the Sandwich estimator, Jack-knife or Bootstrap
methods (as were applied in de Jong et al., 2003) or (preferably) a model that explicitly includes correlation between
the unobserved components per individual (as can be done in mixed logit models). We estimated nested logit models
forcing Biogeme to use the Sandwich estimator and all results in Table 2 come from these estimations (earlier
estimations that did not correct for the panel effect had standard t-ratios that were higher by a factor of about two).
For commuting by car, we find a distinct negative influence of time in congested conditions, on top of the negative
influence of total travel time, but for the other purposes this is not significant.
Table 2. Estimation results for nested logit models, by travel purpose
Commuting
Business
Other
Number of observations
4824
3054
5271
t-ratio is
relative to 0
or 1
Loglikelihood
-5324.9
-3140.3
-5794.3
Rho-square
0.204
0.258
0.207
Coefficient
t-ratio
Coefficient
t-ratio
Coefficient
t-ratio
Car cost [€]
-0.039
-3.4
-0.0066
-1.0
-0.014
-2.8
0
Train cost [€]
-0.010
-1.2
-0.0089
-1.5
-0.025
-3.4
0
Car time [min]
-0.0063
-1.9
-0.0045
-2.1
-0.0060
-2.3
0
Congested car time [min]
-0.013
-2.9
-0.0038
-1.2
-0.0025
-1.0
0
Train time [min]
-0.011
-4.1
-0.0049
-2.1
-0.0031
-2.3
0
Frequency [per hr]
0.028
2.1
0.0066
0.6
0.015
2.1
0
Probability of a seat
0.022
1.8
0.036
1.9
0.032
2.6
0
Nest TOD for car
1.680
2.2
2.070
1.3
2.780
1.9
1
Nest TOD for train
1.520
1.7
1.960
1.7
1.920
2.5
1
Scale SP2 vs SP1
1.130
1.2
1.290
1.9
1.240
2.0
1
Scale train vs car
0.986
-0.1
1.160
0.4
1.560
1.0
1
And many other dummy coefficients not shown here
If we divide the time coefficient by the cost coefficient and multiply the outcomes (still in minutes) by 60, we get
the implied Values of Time (VoT) per hour. These can be found in Table 3 (by mode and purpose). The VoTs,
especially for commuting-train and for business and other by car, are quite high, as the official VoTs for cost-benefit
analysis are about 9-13, 23-32 and 8-9 euro at the moment for commuting, business and other respectively
(Kouwenhoven et al., 2014; Rijkswaterstaat, 2018). In these cases, the precision is also lower (larger standard
deviations). In the models that were estimated on the 2000-2001 TOD SP data, the implied VoTs were also high, and
by about the same factor as we find now. The error components models in de Jong et al. (2004) give, after conversion
from guilders to euros and correcting for inflation, VoTs of 15-49 euro (of 2019) for commuting, 47-59 for business
and 6-71 for other (including education). A possible explanation is that the focus in this research is not so much on
the trade-off between travel time and cost, but of the trade-off between departure time and travel time (and/or cost).
As an aside, the finding that the VoTs from this kind of study ((TOD) have not increased in the period 2000-2019,
whereas real income in this period has increased, is remarkable. Other research into changes in the VoTs over time
also found that the change in VoTs in The Netherlands over time is smaller than the income change over the same
period. (Kouwenhoven et al., 2017). However, we have to be careful in drawing our conclusions on the VoT, since
this survey was not designed as a VoT survey. Also, the sample used is not yet (made) representative for journey
distances and socio-economic characteristics of the travellers, as has been done in the national VoT study
(Kouwenhoven et al., 2014). Moreover, Kouwenhoven et al. (2014) also take account of unobserved heterogeneity,
unlike the nested logit models that were estimated in this new study.
Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129 125
Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000 7
Table 3. The resulting Values of Time (VoT) by mode and purpose. The confidence intervals given refer to plus or minus one standard deviation
VoT (/hr)
Commuting Business Other
Car
10 6
41 43
26 15
Train
65 53
33 26
7 4
The second block of estimated coefficients in Table 2 contains the nest coefficients, one for TOD choice
alternatives within the car mode and one for TOD alternatives within the train mode. All nest coefficients but one
(business car) are significantly (at 90%) different from 1. In the estimated nesting structure TOD choice comes
below mode choice, making TOD the most sensitive of the two choices (more substitution between periods than
between modes). This outcome is in line with Hess and Daly (2007), who also found either this nesting structure or
MNL, depending on the travel purpose. In the Biogeme software that we used for estimation, the nesting coefficients
have a different normalisation than in Alogit, which was used in 2007. In order to obtain nesting coefficients that can
be compared to those from Alogit, we have to take the reciproke: 1/(nest coefficient). The nest coefficients from Table
2 then become 0.60 (car) and 0.66 (train) for commuting, 0.48 (car) and 0.51 (train) for business and 0.36 (car) en
0.52 (train) for other purposes. These values are all between 0 and 1, as required for global consistency with stochastic
utility maximisation.
In Table 4, these nesting coefficient values are compared to those from Hess and Daly (2007), which are still used
in the current version of LMS.
Table 4. The resulting nesting coefficients by purpose and mode in the new study and in Hess and Daly (2007). The confidence intervals given
refer to plus or minus one standard deviation
commuting
Business
Other
Car
Train
Car
Train
Car
Train
This new study
0.60 0.27
0.66 0.39
0.48 0.37
0.51 0.30
0.36 0.19
0.52 0.21
Hess and Daly (2007)
0.40 0.05
-
1.04 0.2
(->MNL*)
1.36 0.3
(->MNL*)
* These nest coefficients are not significantly different from 1. Therefore, a nest coefficient of 1 is used in the LMS, whic h makes it equivalent to
a MNL structure.
For commuting we now find a somewhat larger nesting coefficient than Hess and Daly (2007), though this is
within the error margins. The only other acceptable nested logit model that Hess and Daly (2007) found was for non-
home-based business trips, but in the new version of the LMS this will no longer be a separate travel purpose, so we
did not collect data or estimate a separate model for this. For business tours we now obtain nesting coefficients between
0 and 1, but with large error margins. The nesting coefficients that we find now for other are significantly different
from those of Hess and Daly (2007), which were not significantly different from 1. A possible reason for finding
different nesting coefficients (for car) than in the previous study could be the decision to let two out of four alternatives
on a screen refer to the other (not observed) mode instead of one out of four. Also the use of a D-efficient design in
the new study can have played a role in obtaining significant coefficients (higher precision).
Moreover, this new study also yields nesting coefficients for train users. Hess and Daly (2007) did not include
models for this, so in the current LMS the assumption was made that for train users the nesting coefficients for car
drivers can be used as well. We do find now that, certainly for commuting and business, the nesting coefficients for
car drivers and train users are not significantly different indeed.
The second block of estimated coefficients in Table 2 also contains the scale parameters that scale the unobserved
variance for current train users to that of car users (who got slightly different SP experiments), and likewise for SP2
126 Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129
8 Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000
to that of SP1. In the planned estimation/application of TOD choice in the context of the LMS, these scale coefficients
will no longer be necessary. However, it is good to see that their values are close to 1, which tells us that the
unexplained variance does not differ much between car drivers and train users or SP experiments with and without
higher cost in the peak.
Furthermore, we also estimated a large number of alternative-specific dummies for combinations of the four
alternatives on each screen and whether the respondent was a car driver of train user, and dummies for combinations
of the time periods for the outward journey and the return journey (not presented in Table 2). The time periods used
here are the same as used in the LMS:
Before 6 AM
First shoulder of morning peak: 6-7 AM
Morning peak: 7-9 AM
Second shoulder of morning peak: 9-10 AM
10 AM 3 PM
First shoulder of afternoon peak: 3-4 PM
Afternoon peak: 4-6 PM
Second shoulder of afternoon peak: 6-7 AM
After 7 PM.
As in Hess and Daly (2007), many of the estimated coefficients for TOD combinations are not significant, which
is not surprising given the large number of these dummies that were estimated. Also their significance will depend on
the choice of the reference alternative. In the new LMS, the TOD dummies will be based on RP data (the national
travel survey), because this data source gives a representative pattern over the whole day. Nevertheless, we have to
include these dummies here to get better (less biased) estimates for the other estimated coefficients.
5. Findings, comparison with 2000-2001 and conclusions
The SP data for the choice of time period that were available in The Netherlands for the re-estimation of the LMS
national transport model date back to the years 2000-2001. A new SP survey was carried out (almost) twenty years
later to obtain up-to-date data on this. As in 2000-2001, the choice that is investigated is the simultaneous choice of
mode and time-of-day (TOD). Other similarities between the two studies are:
Tour-based SP survey;
Interviews with car drivers and train users, recruited from a panel;
One SP experiment on travelling in the congested peaks or outside and another SP experiment including
higher travel cost in the peak than off-peak, both with eight choice situations;
Use of the data in a nested logit model for mode and TOD choice.
Differences between the old and the new study are the following:
In 2000-2001 a CAPI survey was carried out and in 2019 a CAWI survey;
In 2000-2001 we presented choice situations with three alternatives referring to the observed mode and one
for another mode, in 2019 we present two alternatives for each of these modes;
In 2019 a D-efficient design was used for generating the SP alternatives, which was not the case in 2000-
2001.
In total, 1094 useable interviews were collected and all the targets in terms of numbers of interviews by mode
and purpose were achieved. Nested logit models were estimated on the new SP data, using the same specifications as
in the previous study for the LMS. The new estimation results are of a similar level of quality as were obtained on the
SP data from 2000-2001. For the nesting coefficients between mode and TOD choice, which in the current LMS are
the key results from the SP estimations, we get results that are significantly different from the outcomes on the old SP
data for some of the travel purposes. We now obtain nest coefficients that are smaller than 1 for all three purposes
commuting, business and other (though not always significantly different from 1), which goes with a model structure
where TOD choice is more sensitive than mode choice. Our tentative conclusion is that TOD choice seems to have
become (relatively to mode choice) more flexible in the past two decades, in line with the trends towards more
Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129 127
Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000 9
flexibility in scheduling activities over the day and a 24 hours economy. Moreover, we now estimate nest coefficients
for both car drivers and train users (until now the assumption that had to be made in the LMS was that the nest
coefficients for train followed those for car).
The values of time (VoTs) that can be calculated from the new models are in most cases larger than the official
CBA values, but of a similar order of magnitude as was found on the data from 2000-2001.
We conclude from the above findings that the new SP data provide a good new source for use in the new LMS
re-estimation project, in combination with the RP data (national travel survey), and possibly also other SP data (such
as the most recent national VoT survey; Kouwenhoven et al., 2014). In The Netherlands we now again have up-to-
date information on mode and TOD choice which can be used in future joint SP/RP modelling. A fall-back option is
also available, which entails only taking the nesting coefficients for TOD alternatives within the same mode (car driver
or train) from models on the new SP data. The models reported here can form a good starting point for this, but further
specification research (e.g. on linear or nonlinear time and cost variables, interaction with household and person
attributes) would probably be worthwhile in this case.
Besides use of the new SP data in a joint RP/SP model in the context of the LMS re-estimation, one could also
use the new SP estimation sample and the models estimated on it directly for policy simulations. A proper method for
doing this would be sample enumeration, with expansion factors and recalibrated alternative-specific constants to
make the application representative. In this way, the results of this study could be used (outside of the LMS) to
investigate the impact of changes in transport time and cost (by TOD), frequency and probability of a seat on the
modal split and the distribution over time periods of Dutch travellers.
Acknowledgements
The work reported here was carried out in a project carried out by Significance and Kantar Public for The Netherlands
Ministry of Infrastructure and Water Management, Rijkswaterstaat, WVL.
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Appendix A. Examples of choice screens
SP1 (car drivers)
Car 1 Car 2 Train 1 Train 2
Outward journey
07:15 - 08:00
08:20 - 09:16
08:12 - 09:10
07:36 - 08:28
Return journey
17:20 - 18:16
14:32 - 15:28
17:30 - 18:29
16:48 - 17:40
Total travel time
1 hr and 41 min.
1 hr and 52 min.
1 hr and 57 min.
1 hr and 44 min.
of which 21 min.
of which 32 min.
in traffic jam
in traffic jam
Total duration of
stay
9 hr and 20 min.
5 hr and 16 min.
8 hr and 20 min.
8 hr and 20 min.
Total cost
€ 3.80,
€ 3.80
€ 6.40
€ 5.80
of which € 0.00
of which € 0.00
for parking
for parking
You can find a seat
every 2 out of 10
trips
every 4 out of 10
trips
You can travel …
4 times per hr
4 times per hr
None of these
First choice
o
o
o
o
o
Second choice
o
o
o
o
o
Gerard de Jong et al. / Transportation Research Procedia 49 (2020) 119–129 129
Gerard de Jong et al./ Transportation Research Procedia 00 (2019) 000000 11
SP2 (car drivers):
Car 1 Car 2 Train 1 Train 2
Travelling outside the peak
(7-9 hr, 16-18 hr) is
33% cheaper
Outward journey
08:20 - 09:10
05:40 - 06:45
09:15 - 10:05
08:20 - 09:10
Return journey
17:50 - 18:50
15:05 - 15:50
17:25 - 18:15
16:55 - 17:45
Total travel time
1 hr and 50 min.
1 hr and 50 min.
1 hr and 40 min.
1 hr and 40 min.
of which 30 min.
of which 30 min.
in traffic jam
in traffic jam
Total duration of
stay
8 hr and 40 min.
8 hr and 20 min.
7 hr and 20 min.
7 hr and 45 min.
Total cost
€ 7.40
€ 3.80
€ 6.40
€ 6.40
of which € 0.00
of which € 0.00
for parking)
for parking)
You can find a seat
every 10 out of 10
trips
Every 4 out of 10
trips
You can travel …
4 times per hr
4 times per hr
None of these
First choice
o
o
o
o
o
Second choice
o
o
o
o
o
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BIOGEME: A free package for the estimation of discrete choice models
  • M Bierlaire
Bierlaire, M., 2003. BIOGEME: A free package for the estimation of discrete choice models, Proceedings of the 3rd Swiss Transportation Research Conference, Ascona, Switzerland.
PandasBiogeme: a short introduction
  • M Bierlaire
Bierlaire, M., 2018. PandasBiogeme: a short introduction, Technical report TRANSP-OR 181219, Transport and Mobility Laboratory, ENAC, EPFL, Lausanne.
Ngene 1.2 User Manual & Reference Guide
  • Choicemetrics
ChoiceMetrics, 2018. Ngene 1.2 User Manual & Reference Guide, ChoiceMetrics, Sydney.