CN106991817B - Method for determining traffic capacity of road sections of multi-level road network - Google Patents

Abstract

The invention provides a multi-stage circuitThe method for determining the traffic capacity of the network section comprises the following steps: s1, acquiring a road distribution condition in a road network, comprising the following steps: dividing a road network into m road sections, expressing a road section set by X, dividing a jth road section xj into n slope sections, expressing a slope section set by Y, expressing a slope length set by Z, S2, respectively calculating the road section capacity Qj when the jth road section achieves the maximum efficacy, S3, calculating the capacity Q of the whole road network according to the road section capacity Qj:

by the method and the device, the traffic capacity of the multi-level road network can be accurately calculated, an accurate result can be obtained, and the application range can be enlarged.

Description

Method for determining traffic capacity of road sections of multi-level road network

Technical Field

The invention relates to a traffic analysis method, in particular to a method for determining traffic capacity of road sections of a multi-level road network.

Background

In the traffic field, traffic capacity of a road network is one of key elements for analyzing road network balance and traffic coordination, in the prior art, a method for determining the traffic capacity of the road network comprises a space-time consumption method, a linear programming method, a cut-set method, a traffic distribution simulation method, a supply analysis method, a narrow-sense road network capacity analysis method and the like, but the conventional method is generally based on a theoretical model, has small limitation and application range, and the final analysis result is inaccurate.

Therefore, in order to solve the above technical problems, it is necessary to provide a new method.

Disclosure of Invention

In view of the above, an object of the present invention is to provide a method for determining traffic capacity of a road segment of a multi-level road network, which can accurately calculate the traffic capacity of the multi-level road network and obtain an accurate result, and can improve a use range.

The invention provides a method for determining the traffic capacity of a road section of a multi-level road network, which comprises the following steps:

s1, acquiring a road distribution condition in a road network, comprising the following steps:

dividing a road network into m road segments, and representing a road segment set by X, wherein X is (X1, X2, …, xj, … xm), and j is 1,2, …, m, and the road network is divided according to different design speeds;

dividing the j-th road segment xj into n slope segments, wherein Y represents a slope segment set, and Z represents a slope length set, wherein Y is (Y1, Y2, …, yk, … yn), Z is (Z1, Z2, …, zk, … zn), and k is 1,2, …, n;

s2, respectively calculating the road section capacity Qj when each j road section achieves the maximum efficacy, wherein:

wherein,

representing the optimal vehicle density of each k-th slope section when the road is at the maximum efficacy;

s3, calculating the capacity Q of the whole road network according to the road section capacity Qj:

further, in step S2, the optimum vehicle density is determined by the following method

S21, establishing a first traffic efficiency model:

k is derived for both sides of the equation of the first traffic performance model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

where kj is the blocking density, v _fα and β are the weights of the traffic density and the interval average speed in the traffic flow respectively, which are the free flow speed;

s22, establishing a second traffic efficiency model:

and respectively deriving k from two ends of the equation of the second traffic efficiency model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

where kj is the blocking density, v _fFor free flow velocity, k _mDensity at maximum flow;

s23, forming a value range according to the density values k obtained by the first traffic efficiency model and the second traffic efficiency model, namely

Taking values within the value range, namely:

further, the blocking density kj is determined by:

s210, road parameters including the friction coefficient phi of the jth road section are obtained _jAverage vehicle length

The speed of the tracking vehicle is V2, the speed of the leading vehicle is V1, the minimum distance between the front end and the tail end of the leading vehicle when the tracking vehicle stops, and the gradient Sj of the j section;

s211, establishing a minimum vehicle tail space model of the tracking vehicle and the front vehicle under the condition that the tracking vehicle does not collide with the front vehicle, and calculating the minimum vehicle tail space d of the tracking vehicle and the front vehicle according to road parameters, wherein:

wherein tr is the response time of the tracking vehicle;

s213, calculating the blocking density kj according to the following formula:

further, in step S210, the average vehicle length is acquired by the following method

Acquiring the vehicle type c of the j section and the length l of the q type vehicle _qAnd the proportion p of the qth vehicle to the total traffic volume of the jth road section _qAnd calculating the average vehicle length according to the following formula

The invention has the beneficial effects that: according to the invention, the attributes of the road network and the attributes of the vehicles are fully considered in the analysis process of the traffic capacity of the multilevel road network, so that the accuracy of the final calculation result of the traffic capacity can be effectively ensured, and the road network is subjected to corresponding segmentation processing in the analysis process, so that the adaptability of the method is effectively improved, the limitations of the existing method are effectively removed, and accurate data support can be provided for traffic management.

Drawings

The invention is further described below with reference to the following figures and examples:

FIG. 1 is a flow chart of the present invention.

Detailed Description

Fig. 1 is a flowchart of the present invention, and as shown in the figure, the method for determining traffic capacity of a multi-level road network section provided by the present invention includes the following steps:

s1, acquiring a road distribution condition in a road network, comprising the following steps:

dividing a road network into m road segments, and representing a road segment set by X, wherein X is (X1, X2, …, xj, … xm), and j is 1,2, …, m, and the road network is divided according to different design speeds;

dividing the j-th road segment xj into n slope segments, wherein Y represents a slope segment set, and Z represents a slope length set, wherein Y is (Y1, Y2, …, yk, … yn), Z is (Z1, Z2, …, zk, … zn), and k is 1,2, …, n;

s2, respectively calculating the road section capacity Qj when each j road section achieves the maximum efficacy, wherein:

wherein,

representing the optimal vehicle density of each k-th slope section when the road is at the maximum efficacy;

s3, calculating the capacity Q of the whole road network according to the road section capacity Qj:

by the invention, the analysis process of the traffic capacity of the multi-level road networkThe method fully considers the self attributes (namely the grade, the gradient and the friction coefficient of the road) of the road network and the attributes of the vehicles, analyzes from the practical angle of the road network, thereby effectively ensuring the accuracy of the final calculation result of the traffic capacity, and performs corresponding segmentation processing on the road network in the analysis process, thereby effectively improving the adaptability of the method, being particularly suitable for the complicated traffic capacity analysis of the road network, effectively removing the limitation of the existing method, and providing accurate data support for traffic management.

In the present embodiment, in step S2, the optimum vehicle density is determined by the following method

S21, establishing a first traffic efficiency model:

k is derived for both sides of the equation of the first traffic performance model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

where kj is the blocking density, v _fα and β are the weights of the traffic density and the interval average speed in the traffic flow respectively, which are the free flow speed;

s22, establishing a second traffic efficiency model:

and respectively deriving k from two ends of the equation of the second traffic efficiency model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

where kj is the blocking density, v _fFor free-flow speed, i.e. design speed, k, under different road grade conditions _mDensity at maximum flow;

s23, forming a value range according to the density values k obtained by the first traffic efficiency model and the second traffic efficiency model, namely

Taking values within the value range, namely:

wherein the optimal density value of the ith road section is

α and β are the weight occupied by the traffic density k and the interval average vehicle speed v in the traffic flow, if the weight of the average vehicle speed is large, the weight of the traffic density is reduced, and if the weight of the average vehicle speed is small, the weight of the traffic density is increased.

In this embodiment, the blocking density kj is determined by the following method:

s210, road parameters including the friction coefficient phi of the jth road section are obtained _jAverage vehicle length

The speed of the tracking vehicle is V2, the speed of the leading vehicle is V1, the minimum distance between the front end and the tail end of the leading vehicle when the tracking vehicle stops, and the gradient Sj of the j section;

s211, establishing a minimum vehicle tail space model of the tracking vehicle and the front vehicle under the condition that the tracking vehicle does not collide with the front vehicle, and calculating the minimum vehicle tail space d of the tracking vehicle and the front vehicle according to road parameters, wherein:

wherein tr is the response time of the tracking vehicle;

s213, calculating the blocking density kj according to the following formula:

by the method, the traffic jam density can be accurately determined, and the accuracy of the result is facilitated.

In the present embodiment, in step S210, the average vehicle length is obtained by the following method

Acquiring the vehicle type c of the j section and the length l of the q type vehicle _qAnd the proportion p of the qth vehicle to the total traffic volume of the jth road section _qAnd calculating the average vehicle length according to the following formula

By the method, the average vehicle length can be calculated quickly and accurately, and guarantee is provided for subsequent calculation.

Finally, the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting, although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all of them should be covered in the claims of the present invention.

Claims (3)

1. A method for determining the traffic capacity of road sections of a multi-level road network is characterized by comprising the following steps: the method comprises the following steps:

s1, acquiring a road distribution condition in a road network, comprising the following steps:

dividing a road network into m road segments, and representing a road segment set by X, wherein X is (X1, X2, …, xj, … xm), and j is 1,2, …, m, and the road network is divided according to different design speeds;

dividing the j-th road segment xj into n slope segments, wherein Y represents a slope segment set, and Z represents a slope length set, wherein Y is (Y1, Y2, …, yk, … yn), Z is (Z1, Z2, …, zk, … zn), and k is 1,2, …, n;

s2, respectively calculating the road section capacity Q when the jth road section achieves the maximum efficacy _jWherein:

wherein, represents the optimal vehicle density for the kth slope segment when the road is at maximum efficacy;

determining an optimal vehicle density by

S21, establishing a first traffic efficiency model:

k is derived for both sides of the equation of the first traffic performance model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

wherein k is _jTo block density, v _fα and β are the weights of the traffic density and the interval average speed in the traffic flow respectively, which are the free flow speed;

s22, establishing a second traffic efficiency model:

and respectively deriving k from two ends of the equation of the second traffic efficiency model:

when in use

The traffic efficiency of the road is the maximum, and at the moment, the following results can be obtained:

wherein k is _jTo block density, v _fFor free flow velocity, k _mDensity at maximum flow;

s23, forming a value range according to the density values k obtained by the first traffic efficiency model and the second traffic efficiency model, namely Taking values within the value range, namely:

s3, according to the road section capacity Q _jCalculating the capacity Q of the whole road network:

2. the method for determining the traffic capacity of a road segment of a multi-level road network according to claim 1, wherein: the blocking density k is determined by _j：

S210, road parameters including the friction coefficient phi of the jth road section are obtained _jAverage vehicle length

Tracking vehicle speed v ₂Speed v of the leading vehicle ₁The minimum distance between the head and the tail of the front vehicle when the tracking vehicle stops and the gradient Sj of the jth road section;

s211, establishing a minimum vehicle tail space model of the tracking vehicle and the front vehicle under the condition that the tracking vehicle does not collide with the front vehicle, and calculating the minimum vehicle tail space d of the tracking vehicle and the front vehicle according to road parameters, wherein:

wherein, t _rTo track vehicle response times;

s212, calculating the blocking density k according to the following formula _j：

3. The method of determining traffic capacity of road segments of multi-level road network according to claim 2, characterized in that: in step S210, the average vehicle length is acquired by the following method

Acquiring the vehicle type c of the j section and the length l of the q type vehicle _qAnd the proportion p of the qth vehicle to the total traffic volume of the jth road section _qAnd calculating the average vehicle length according to the following formula

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