Speed-volume-density relationship and capacity are key elements in modelling traffic operations, designing roadways, and evaluating facility performance. This paper uses a modified five-parameter logistic model to describe the speed-density relationship. The calibrated speed-density models show that the stop-and-go speed (Vb) and shape parameters (θ1 and θ2) are similar for work zones and the nonwork zone site. Accordingly, an operational capacity prediction method is proposed. To demonstrate the effectiveness of the proposed method, the predicted operational capacities are compared with the field data, Highway Capacity Manual method, the output of WorkZoneQ software, and the ensemble tree approach under different work zone scenarios. Furthermore, a lifetime distribution prediction framework for stochastic capacity of work zones is proposed. The predicted lifetime distribution can well capture the tendency of the observed work zone capacities.
Iowa Department of Transportation1. Introduction
The conflict between the aged infrastructure and the continuous growth of traffic demand makes the maintenance and repair activities on roadways become commonplace. These activities usually cause traffic delays and safety concerns [1, 2]. Traffic control and management strategies, such as imposing reduced speed limits and coordinating lane closure schedules, have been applied to alleviate the impact of work zones [3–5]. To properly design work zone management strategies, accurate prediction of work zone capacity is crucial. Numerous statistical and simulation-based methods have been proposed to estimate or predict work zone capacity [3, 6–12]. However, only a few work zone capacity estimation methods were derived from speed-flow relationships [3, 10, 11], although speed, volume, and density relationship have been widely used to estimate the capacity of freeways [13].
Moreover, work zones usually induce bottlenecks and cause traffic breakdown. Traffic breakdown does not always occur at the maximum flow rate because of its stochastic nature [14, 15]. Therefore, predicting work zone capacity lifetime distribution, referred to as prebreakdown distribution in some literature, is crucial for transportation agencies to evaluate the traffic flow reliability at the work zone site. Several studies have investigated capacity distributions based on lifetime data analysis [14, 16, 17]. However, none of the existing methods focus on predicting work zone capacity lifetime distribution.
In this study, speed-volume-density relationships of both work zones and nonwork zone sites are developed. The work zone capacity is predicted based on the speed-volume-density models and the relationship between free-flow speed and work zone characteristics. The work zone capacity lifetime distribution is predicted based on the capacity distribution before work zone and work zone characteristics.
2. Literature Review
In the literature, the definition of capacity can be categorized into operational capacity and stochastic capacity [18, 19]. Operational capacity is usually derived from the maximum flow rate [20], the queue discharge rate [6, 9, 21], and the speed-volume curve [11, 22, 23]. Queue discharge flow rate, which is measured after traffic breakdown, is generally lower than the sustaining flow rate before breakdown [24, 25]. Maximum flow rate is a single measurement and might be unreliable [24, 26]. The speed-volume curve is developed based on observations measured before and after traffic breakdown and describes the characteristics of traffic flow at the study site. Thus, the capacity derived from speed-volume curve is defined as the operational capacity in this paper. Furthermore, Kondyli et al. [24] and Highway Capacity Manual (HCM) 6th edition [27] recommended using prebreakdown flow rate as freeway capacity. However, previous research has shown that prebreakdown flow rates follow probability distributions [17, 19, 28]. In this paper, the distribution of prebreakdown flow rates is defined as stochastic capacity [18, 22].
Work zone operational capacity estimation and prediction methods can be categorized into three groups: simulation based, nonparametric, and parametric methods [2]. Microscopic traffic simulation models, such as CORSIM and VISSIM, have been applied to estimate the operational capacity of work zones with different lane closure configurations [29–31]. To replicate real world traffic conditions, the microscopic simulation models need to be calibrated to local conditions, which is usually a tedious and expensive procedure. Nonparametric methods, including neural-fuzzy logic, decision tree, and ensemble tree models, have been used to predict work zone operational capacity [12, 32, 33]. These nonparametric methods usually need extensive historical traffic data to provide reliable prediction. Parametric approaches use predetermined coefficients of the predictors that are calibrated based on the data collected from the work zone site to predict work zone operational capacity. For example, Krammes and Lopez [9] and Kim et al. [8] developed multiregression models to predict short-term work zone operational capacity. Al-Kaisy and Hall [6] and Al-Kaisy et al. [34] proposed a generic multiplicative model to predict the long-term work zone operational capacity based on the traffic data collected from Ontario, Canada. They investigated the effects of grade, the day of week, and weather condition on work zone operational capacity.
In addition, Highway Capacity Manual (HCM) 6th edition [27] proposed a method to calculate the work zone operational capacity. First, the work zone queues discharge rate is calculated as follows:(1)QDRwz=2093-154×fLCSI-194×fBr-179×fAT+9×fLAT-59×fDNwhere QDRwz is the work zone queue discharge rate (pc/hr/ln); fLCSI is the lane closure severity index, fLCSI=totalnumberoflanes/numberofopenlanes2; fBr is the barrier type, 0 for concrete, 1 for plastic cone or drum; fAT is the area type, 0 for urban areas, 1 for rural areas; and fAT is the lateral distance from the edge of travel lane adjacent to the work zone to the barrier, barricades, or cones; and fDN is 1 for daytime, 0 for night time.
Since the unit of QDRwz is passenger car per hour per lane, the capacity adjustment factor is applied to convert it to vehicle per hour per lane.(2)CAFMIX=CAFAO-CAFT-CAFGwhere CAFMIX is the mixed-flow capacity adjustment factor; CAFAO is the capacity adjustment factor for the auto-only case, which defaults to 1.0; CAFT is the capacity adjustment factor for the percentage of trucks in mixed-flow conditions, CAFT=0.53×TruckPercentage0.72; and CAFG is the capacity adjustment factor for grade for segment j in mixed-flow conditions, which is 0 in this study.
Therefore, the work zone operational capacity can be calculated as follows: (3)qc=QDRwz100-αwz×100×CAFMIXwhere αwz is the percentage drop in capacity at the work zone due to queuing conditions (%). The recommended value is 13.4% for freeway work zone. qc is the work zone operational capacity.
Over the years, several researchers tried to derive work zone operational capacity from speed-volume-density relationship to provide a reliable estimate [3, 10, 11, 35, 36]. Numerous models have been developed to describe the speed-volume-density relationship, including single-regime and multiregime models. Two parameter single-regime models, such as Greenshields model [37] and Newell’s model [38], usually cannot fit traffic data under congested and uncongested conditions at the same time. Multiregime models, such as Edie model [39], modified Greenberg model [40], and the cluster analysis based model [41], use two or more curves to fit traffic data in different regimes separately. The main challenge of applying multiregime model is to determine breakpoints in a systematic way [42]. To overcome these limitations, MacNicholas [43] proposed a five-parameter logistic speed-density model, which can fit the congested and uncongested regimes using one curve. Wang et al. [42] pointed out that the five-parameter logistic speed-density model outperforms the three-parameter logistic speed-density model and the existing models, such as Greenshields model, Greenberg model, Modified Greenberg model, Van Aerde model, and Newell’s model. Thus, the five-parameter logistic speed-density model is adopted in this paper to fit the traffic data collected at work zone sites.
Furthermore, work zone capacity distribution estimation and prediction methods have been introduced in recent years. For example, Weng and Yang [44] proposed a method to determine work zone capacity distribution based on probabilistic two-regime speed-flow relationships. Weng and Yan [45] developed a truncated lognormal distribution model to predict work zone capacity, where the distribution parameters are formulated as a linear function of work zone characteristics. Lu [46] proposed a framework to predict work zone capacity range based on single-regime speed-flow relationships. In addition, previous studies found that traffic flow breakdown occurs with some probability at various flow rates that are lower than the maximum flow rate, referred to as stochastic capacity [14, 15, 47]. A lifetime distribution has been used to describe the probabilistic distribution of prebreakdown capacity. Different factors influencing freeway stochastic capacity have been investigated, including weather [17] and incidents [48]. In this study, the lifetime distribution is used to describe stochastic capacity of work zones.
In practice, HCS, QuickZone, QUEWZ, and WorkZoneQ are the commonly used software packages to estimate work zone operational capacity [49, 50]. In addition, the operational capacity estimation method proposed by Highway Capacity Manual 6th (HCM) [27] is also widely used by transportation agencies. In this paper, the results based on WorkZoneQ and HCM are compared with the proposed model. Moreover, the proposed model is compared with the work zone operational capacity prediction model proposed by Weng and Meng[12], which is based on the ensemble tree approach.
2.1. Objective and Contribution
The objective of this paper is to predict work zone operational capacity based on speed-volume-density relationship and predict the lifetime distribution of work zone capacity. The operational capacity prediction model captures the relationship between operational capacity and work zone characteristics, considering the impact of work zone on free-flow speed. The stochastic capacity is predicted based on the capacity distribution before work zone and work zone characteristics and is described using a Weibull distribution.
The contribution of this paper is two-fold. First, we propose a method to predict the speed-volume-density relationship and the operational capacity under work zone conditions by incorporating work zone characteristics in the five-parameter logistic speed-density model. Second, we propose a method to predict work zone capacity lifetime distribution considering the stochastic nature of flow breakdown. The proposed methods could help traffic engineers to predict work zone capacity and its distribution and design appropriate traffic management strategies to avoid long periods of oversaturation caused by work zones.
3. Data Description
Traffic flow rate, speed, and occupancy data were collected by Iowa Department of Transportation (DOT) using Wavetronix radar sensors placed in the work zone areas. Four work zones in Iowa during the 2015 and 2016 construction seasons are investigated in this study.
Work zone data: Traffic volume, speed, and occupancy data were collected when the work zones were active in 2015 and 2016. The date and time of work zones are determined by combining traveler information data from Iowa DOT and the contractor reports and plans.
Baseline data: Traffic volume, speed, and occupancy data were collected from May to August in 2014 from the sensors located in the same or nearby locations of the work zone sites in Iowa City and Council Bluffs. Traffic data were also collected from May to August in 2015 at a freeway section in Des Moines where no work zone presented. These data are treated as the baseline for the work zones in Quad Cities and Sioux City because the Des Moines location has the same speed limit and similar geometric characteristic as the Quad Cities and Sioux City sites.
The configurations and layouts of the work zones are summarized in Table 1 and Figure 1, respectively. The sensors are located at the upstream of the merging area in order to measure prebreakdown flow rates [28, 51].
Summary of work zone configurations.
City
Work Zone
Truck Percentage
Speed limit (mph)
Work Type
Control Type
Barrier Type
Area Type
Work Time
Original
Work zone
Quad Cities
I80 WB
29.63%
65
55
Bridge deck overlay
Lane closure
Plastic Drum
Urban
Daylight
Quad Cities
I80 EB
29%
65
55
Bridge deck overlay
Lane closure
Plastic Drum
Urban
Daylight
Sioux City
I29 NB
13.24%
65
55
Pavement Reconstruction
Lane closure and shift
Plastic Drum
Urban
Daylight
Iowa City
I380 NB
15.97%
70
55
Bridge deck overlay
Lane closure /shift
Plastic Drum
Urban
Daylight
Council Bluffs
I80/I29 WB
17.23%
65
55
Road construction
Lane closure /shift
Concrete
Urban
Daylight
Work zone layouts.
Quad Cities
Sioux City
Iowa City
Council Bluffs
Based on the volume and speed measurements, the density is calculated using (4)k=qVwhere V is the speed (mi/h); k is the density (veh/mile/ln); and q is the volume (veh/hr/ln).
To focus on the traffic impact of work zones, the data collected on rainy days were removed. In addition, erroneous measurements were removed from the raw data. In particular, the average effective vehicle length (AEVL) is used to identify anomalies [52]. AEVL is calculated using speed, volume and occupancy collected from Wavetronix sensors [53], as shown in (5). The observations that result in AEVLs out of the normal vehicle length range, namely, 10 to 75 ft (3.048 to 22.86 m) [54], were removed from the dataset. The overall data reduction rate is 24.5%.(5)AEVL=5280×V×Oqwhere AEVL is average effective vehicle lengths (feet); and O is the occupancy.
4. Methodology4.1. Operational Capacity
According to MacNicholas’ model [43], the function of general logistic speed-density relationship is expressed as (6)V=Vb+Vf-Vb1+expk-kt/θ1θ2where Vf is the free-flow speed (mi/h); Vb is the average speed at stop-and-go condition (mi/h); kt is the turning point that the speed–density curve transitions from free-flow to congested flow (veh/mi/ln); θ1 is the scale parameter; and θ2 is the parameter controls the lopsidedness of the curve.
By rearranging (6), traffic density can be written as follows:(7)k=kt+θ1lnexplnVf-Vb/V-Vbθ2-1where ln· is the natural logarithm.
By substituting (7) into (4), the speed-volume function is derived as follows:(8)q=ktV+θ1lnexplnVf-Vb/V-Vbθ2-1VThe relationship between turning point (kt) and inflection point (kIP) in the five-parameter logistic model is written in [42](9)kt=kIP+θ1lnθ2where kIP is the inflection point, where the logistic speed-density curve switches from being concave to convex.
Wang et al. [42] pointed out that kt has linear relationship with θ1 and θ2. In order to remove the collinearity between kt and θ1 and θ2, α is introduced. In other words, kt is written as a function of α, θ1, θ2, Vb, and Vf. When θ2 equal 1, kt=kIP=kc [42]. Therefore, we assume(10)kc=kIP+αθ1lnθ2where kc is the density at operational capacity (veh/mi/ln).
As a result, (11)Vc=Vb+Vf-Vb1+θ2α-1θ2where Vc is the speed at operational capacity (mi/h).
Using the speed-volume relationship, the operational capacity is reached when the following two conditions are met:(12)∂q∂V=∂k∂V·V+k=0(13)∂2q∂V2=∂k∂V+∂2k∂V2·V+∂k∂V<0The derivations of the first condition and the second condition are shown in Appendix A.
Based on the first condition (i.e., (12)), the inflection density is derived as follows:(14)kIP=θ1Vb1+θ2α-1θ2+Vf-Vb1+θ2α-1θ2αVf-Vb-αθ1lnθ2As a result,(15)kt=θ1Vb1+θ2α-1θ2+Vf-Vb1+θ2α-1θ2αVf-Vb+1-αθ1lnθ2The derivation of (14) is shown in Appendix B.
Therefore, the modified five-parameter logistic speed-density relationship and speed-volume relationship are shown as follows:(16)k=θ1Vb1+θ2α-1θ2+Vf-Vb1+θ2α-1θ2αVf-Vb+1-αθ1lnθ2+θ1lnexplnVf-Vb/V-Vbθ2-1(17)q=θ1Vb1+θ2α-1θ2+Vf-Vb1+θ2α-1θ2αVf-Vb+1-αθ1lnθ2+θ1lnexplnVf-Vb/V-Vbθ2-1VBased on (15), the turning point changes with free-flow speed, average speed at stop-and-go condition, θ1, θ2, and α. θ1 and θ2 are the shape parameters of the speed-density curves. In this study, two assumptions are made:
Vb, θ1, and θ2 remain the same during the work zone as the ones before work zone.
The same type of work zones has the same value of α.
From the second condition derived from (13), the exponential function is always greater than 0. Since θ1 is positive, when explnVf-Vb/V-Vb/θ2-1×θ2×V-2Vb+V is greater than 0, the condition stated in (13) is satisfied. As a result, we assume that(18)explnVf-Vb/Vc-Vbθ2-1×θ2×Vc-2Vb+Vc>0When Vc≥2Vb, the second condition is satisfied.
As a result, the operational capacity can be calculated as follows:(19)qc=maxq,Vϵ2Vb,Vf
4.2. Stochastic Capacity
In previous research, flow breakdown is identified when speed drops from free-flow speed and the low speed is sustained for a certain time duration (i.e., minimum breakdown duration) [51, 55]. Accordingly, Kim et al. [17] proposed a criterion to classify breakdown and stochastic capacity, as follows:
If the speed in time interval i is above a threshold speed and the speed in the next time interval i+1 is below the threshold speed, and the low speed is sustained for at least 15 min, breakdown is assumed to start in time interval i+1, and the flow rate in time interval i is defined as the stochastic capacity.
According to Brilon et al. [51], when a breakdown occurred, the prebreakdown flow rate is considered a true estimate of stochastic capacity, which is a censored value. When the breakdown did not occur, the flow rates are created as uncensored values. Considering both the censored and the uncensored values, a survival analysis approach is applied to estimate the lifetime distribution of the capacity using the maximum likelihood estimation (MLE). The likelihood function is defined as follows [56]:(20)L=∏i=1nfqiδi·1-Fqi1-δiwhere n is number of observations; δi is 1, if uncensored, and 0, otherwise; f· is probability density function; and F· is cumulative distribution function.
Weibull distribution has been calibrated and suggested for freeway reliability analysis by Al-Deek and Emam [57] and Brilon et al. [51] and is used to fit the observations in this paper.(21)Fq=1-e-q/σswhere σ is scale parameter; and s is shape parameter.
The mean of the stochastic capacity distribution is given by(22)Eq=σ·Γ1+1swhere Γ· is the gamma function.
To investigate the relationship between the scale parameter and the operational capacity and the relationship between the scale parameter and the mean stochastic capacity, data from the study of [22] and the data collected in Iowa are summarized in Table 2. The mean of stochastic capacity is derived based on (22).
Operational capacity, mean and parameters of capacity distribution from an existing study and field data.
Source
Location
s
σ
Operational capacity(veh/hr/ln)
Eq (veh/hr/ln)
Liu et al. (2011)
SR-91
7.55
1950
1550
1831
17.68
2565
2051
2489
Iowa
I-35/80
17.96
2238
2150
2173
I-29
13.43
2368
1980
2278
I-380
8.63
2350
2235
2221
Work Zone
I80 WB
11.04
1478
1376
1412
I80 EB
15.16
1503
1267
1452
I29 NB
14.45
1475
1206
1423
The relationship between scale parameter and operational capacity is plotted in Figure 2. The scale parameter and operational capacity is highly correlated, with an R-square of 0.88. As a result, the linear relationship between scale parameter (σ) and operational capacity is written as(23)qc=A·σ+Bwhere A, B are coefficients, which are 0.8729 and -10.888, respectively.
Relationship between the scale parameter and the operational capacity.
The relationship between mean stochastic capacity and σ is plotted in Figure 3. The scale parameter and the mean stochastic capacity is highly correlated, with an R-square of 0.99. Accordingly, the linear relationship between scale parameter (σ) and mean of stochastic capacity distribution is shown as follows:(24)Eq=C·σ+Dwhere, C, D are coefficients, which are 0.9743 and -22.644 respectively.
Relationship between the scale parameter and the mean capacity.
According to (24) and (22), the relationship between the shape parameter (s) and the scale parameter (σ) is derived as follows:(25)s=1Γ-10.97436-22.644/σ-1
4.3. Work Zone Capacity Distribution Prediction
The work zone capacity and its lifetime distribution prediction framework is proposed, as follows.
Step 1.
Estimate the five-parameter logistic model and the capacity distribution using traffic data collected before work zones. The function “nls” in R statistics package [58] is utilized to fit the speed-density curve based on the traffic data.
Step 2.
Determine the mean work zone free-flow speed based on HCM (2016):(26)Vf=9.95+33.49×fsr+0.53×fs-5.6×fLCSI-3.94×fBr-1.71×fDN-1.45×fNrwhere fsr is the ratio of the normal speed limit to work zone speed limit; fs is speed limit of work zone (mi/h); and fNr is the number of ramps within 3 miles (4.8 km) upstream and 3 miles (4.8 km) downstream.
Step 3.
Determine α based on work zone type.
Step 4.
Calculate the work zone operational capacity using Equation (17) and (19). In particular, Vb, θ1, and θ2 are determined in Step 1. α is determined in Step 3. The free-flow speed is determined in Step 2.
Step 5.
Calculate the scale parameter of the work zone capacity distribution based on (23) and the operational capacity determined in Step 4.
Step 6.
Calculate the shape parameter of the work zone capacity distribution based on (25) and the scale parameter from Step 5.
5. Results5.1. Operational Capacity
The estimated traffic speed-volume-density relationships for different work zones are compared with the baseline non-work zone conditions. The calibrated parameters are summarized in Table 3.
Parameters of logistic speed-density models.
Data Source
Vf(mi/h)
Vb(mi/h)
kt (mi/h)
θ1
θ2
α
Non-work Zone
69.39
5.14
34.95
7.61
0.35
0.489
Work Zone
I80 WB
63.74
5.32
21.02
7.53
0.37
-0.263
I80 EB
64.46
5.06
24.54
7.82
0.37
-0.274
I29 NB
51.67
5.17
20.54
7.51
0.38
-0.289
Table 3 shows that free-flow speeds and turning density are smaller at the work zone sites compared to the ones at the nonwork zone site. The stop-and-go speed (Vb) and shape parameters (θ1 and θ2) are similar for work zones and non-work zone sites. Moreover, the values of α at work zone sites are significantly smaller than the one at the nonwork zone site. However, the values of α at different work zones are similar. Note that all the work zones considered in this study are lane closure ones. Other types of work zones might result in different α values. In the subsequent analysis, α of work zones is set as -0.27.
The speed-volume-density relationships before and after work zone started are compared in Figures 4 and 5. In order to investigate the relationship between work zone capacity and the free-flow speed, Vb, θ1, and θ2 that are calibrated based on the before work zone data are assumed to remain the same during the work zone. Based on the predicted free-flow speed, the predicted operational capacity is close to the capacity estimated from the work zone data. The predicted speed-volume-density relationship follows the pattern of the field data collected at work zone sites.
Speed-volume relationships before and during work zone.
Council Bluffs
Iowa City
Speed-density relationships before and during work zone.
Council Bluffs
Iowa City
Additionally, the estimated and predicted operational capacities are compared with the capacity estimates by WorkZoneQ software, HCM, the maximum 15-minute flow rate, and the operational capacities predicted by the model proposed by Weng and Meng [12]. As shown in Table 4, the modified five-parameter logistic model generates similar results as WorkZoneQ and HCM. The maximum 15-minute flow rate tends to overestimate capacity, compared to logistic model and WorkZoneQ results. The work zone in Iowa City, which has a larger free-flow speed reduction, has a lower operational capacity. The work zones that have similar free-flow speed reduction demonstrate similar capacities. Moreover, the predicted operational capacities based on the proposed method match the estimated values better than the Weng and Meng [12] method.
Operational capacities from the proposed method, HCM, Weng and Meng method [12], WorkZoneQ and maximum 15-minute flow rate.
City
Work Zone
Maximum 15-min flow rate (veh/hr/ln)
Estimated operational capacity (veh/hr/ln)
Predicted operational capacity (veh/hr/ln)
HCM
Logistic Model
WorkZoneQ
Proposed method
Weng and Meng[12]
Quad Cities
I80 WB
1572
1239
1267
1296
1252
1383
Quad Cities
I80 EB
1488
1245
1206
1296
1318
1383
Sioux City
I29 NB
1512
1394
1413
1313
1257
1138
Iowa City
I-380 NB
1296
1199
1058
1424
1008
1383
Council Bluffs
I80/I29 WB
1524
1517
1376
1313
1281
1138
In Figure 6, the range of the predicted operational capacity of work zone (i.e., the shaded area) is compared with the results reported in the literature. The predicted capacities tend to be lower than the work zone operational capacities in the literature. One of the reasons is that maximum 15-min flow rate was used as operational capacities in most of the previous studies.
Comparison of the predicted capacity and the results from the existing studies.
5.2. Capacity Distribution
Based on the predicted operational capacity from Table 4, the scale parameter of work zone capacity lifetime distribution can be calculated. The parameters of stochastic capacity distributions before and during work zone started are shown in Table 5. The scale parameters of work zone are significantly smaller than the ones before work zone.
Parameters of Fitted and Predicted Distribution Functions.
City
Before
Work zone
Estimated
Estimated
Predicted
s
σ
s
σ
s
σ
Iowa City
8.64
2350
7.82
1199
11.56
1167
Council Bluffs
13.44
2368
11.04
1478
13.03
1480
The predicted and estimated work zone stochastic capacity distribution are compared, as shown in Figure 7. The predicted work zone stochastic capacity distribution captured the tendency of the estimated work zone stochastic capacity distribution well.
Predicted and estimated stochastic capacity distributions.
Iowa City
Council Bluffs
The errors in the proposed capacity distribution prediction approach could be attributed to several factors. First, the difference between predicted operational capacity and the ground truth operational capacity may cause errors in predicting the scale parameter of work zone. Second, the data used to calibrate the relationship between scale parameter and shape parameter is limited.
6. Conclusions
The effects of work zones on traffic speed-volume-density curves and the roadway capacity are investigated using traffic data collected on freeways in Iowa, USA. A modified five-parameter logistic model is developed to describe the speed-density relationship. The calibrated speed-density models show that the free-flow speed and turning density are smaller when work zone is active compared to non-work zone conditions. Moreover, based on the logistic speed-density model, an operational capacity prediction method is proposed considering the relationship between free-flow speed and work zone characteristics. The performance of the proposed work zone capacity prediction method is evaluated using field data. The logistic model-based method can predict the speed-density relationship that is close to the estimated one from the field data. The predicted work zone operational capacities are similar to the results from WorkZoneQ and HCM and are generally smaller than the maximum 15-min flow rate. Moreover, the predicted operational capacities based on the proposed method is closer to the estimated values than the one proposed by Weng and Meng [12].
Furthermore, a work zone distribution prediction framework is proposed. Based on existing studies and the field data, a linear relationship between the scale parameter (σ) and the operational capacity is established. The predicted capacity distribution can well capture the tendency of the distribution estimated based on the field data.
There are some caveats in the present paper. First, only work zones with lane closure are considered in the study. In the future, other types of work zones need to be investigated. Second, only free-flow speed and α are considered as dependent variables that influence the speed-density curve. Future studies should examine the impact of work zone intensity, traffic control type, and road configuration on the other parameters of the logistic model. Third, the linear relationship between scale parameter (σ) and operational capacity is based on the limited data from existing studies and the field data. In the future, comprehensive datasets, including different impacting factors needs to be considered.
AppendixA. Sufficient Conditions for Capacity
The First Condition(A.1)∂k∂V=θ1×∂∂VlnexplnVf-Vb/V-Vbθ2-1Derivation(A.2)∂∂VlnexplnVf-Vb/V-Vbθ2-1=1explnVf-Vb/V-Vb/θ2-1×∂∂VexplnVf-Vb/V-Vbθ2-1=1explnVf-Vb/V-Vb/θ2-1×∂∂VexplnVf-Vb/V-Vbθ2=explnVf-Vb/V-Vb/θ2θ2explnVf-Vb/V-Vb/θ2-1×∂∂VlnVf-VbV-Vb=-V-Vb/Vf-Vb×explnVf-Vb/V-Vb/θ2θ2explnVf-Vb/V-Vb/θ2-1×∂∂VVf-VbV-Vb=-V-Vb×explnVf-Vb/V-Vb/θ2θ2explnVf-Vb/V-Vb/θ2-1×∂∂V1V-Vb=-explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1As a result,(A.3)∂q∂V=k-θ1×V×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1As a result(A.4)∂q∂V=k-V×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1=0The Second Condition(A.5)∂2q∂V2=-θ1×explnVf-Vb/V-Vb/θ2explnVf-Vb/V-Vb/θ2-1×θ2×V-2Vb+Vθ2×V-Vb2×explnVf-Vb/V-Vb/θ2-12Derivation(A.6)∂2q∂V2=θ1×∂∂VlnexplnVf-Vb/V-Vbθ2-1-θ1×∂∂VV×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1=-θ1×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1-θ1×∂∂VV×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1∂∂VV×explnVf-Vb/V-Vb/θ2V-Vb×θ2explnVf-Vb/V-Vb/θ2-1=1θ2×∂∂VV×explnVf-Vb/V-Vb/θ2V-Vb×explnVf-Vb/V-Vb/θ2-1=1θ2×∂/∂VV×explnVf-Vb/V-Vb/θ2V-Vb×explnVf-Vb/V-Vb/θ2-1-V×explnVf-Vb/V-Vb/θ2×∂/∂VV-Vb×explnVf-Vb/V-Vb/θ2-1V-Vb2×explnVf-Vb/V-Vb/θ2-12∂∂VV×explnVf-Vb/V-Vbθ2=explnVf-Vb/V-Vbθ2+∂∂VexplnVf-Vb/V-Vbθ2=explnVf-Vb/V-Vbθ2-V×explnVf-Vb/V-Vb/θ2θ2×V-Vb∂∂VV-Vb×explnVf-Vb/V-Vbθ2-1=explnVf-Vb/V-Vbθ2-1-explnVf-Vb/V-Vb/θ2θ2As a result,(A.7)∂2q∂V2=θ1×-V×exp2lnVf-Vb/V-Vb/θ2θ2×V-Vb2×explnVf-Vb/V-Vb/θ2-12-2exp2lnVf-Vb/V-Vb/θ2θ2×V-Vb×explnVf-Vb/V-Vb/θ2-1+V×explnVf-Vb/V-Vb/θ2θ2×V-Vb2×explnVf-Vb/V-Vb/θ2-1+V×explnVf-Vb/V-Vb/θ2θ2×V-Vb2×explnVf-Vb/V-Vb/θ2-1=-θ1×explnVf-Vb/V-Vb/θ2explnVf-Vb/V-Vb/θ2-1×θ2×V-2Vb+Vθ2×V-Vb2×explnVf-Vb/V-Vb/θ2-12
B. Derivation of the Inflection Density
(B.1)∂q∂V=kc-θ1×Vc×explnVf-Vb/Vc-Vb/θ2Vc-Vb×θ2explnVf-Vb/Vc-Vb/θ2-1=0By substituting (5) and (6) into it, we have(B.2)kIP+αθ1lnθ2=θ1×Vb+Vf-Vb/1+θ2α-1θ2×expln1+θ2α-1θ2/θ2Vf-Vb/1+θ2α-1θ2×θ2expln1+θ2α-1θ2/θ2-1As a result,(B.3)kIP=θ1Vb1+θ2α-1θ2+Vf-Vb1+θ2α-1θ21/αVf-Vb-αθ1lnθ2
Data Availability
The data were provided by Iowa Department of Transportation.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
Acknowledgments
This research is sponsored by the Iowa Department of Transportation. The views and opinions expressed are those of the authors and do not necessarily reflect the views of the sponsoring agency.
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