RouteSolverProperties (arcpy.na)

Resumen

Proporciona acceso a las propiedades de análisis desde una capa de análisis de red de ruta. La función GetSolverProperties se utiliza para obtener un objeto RouteSolverProperties desde una capa de análisis de red de ruta.

Debate

El objeto RouteSolverProperties proporciona acceso de lectura y escritura a todas las propiedades de análisis de una capa de análisis de red de ruta. El objeto se puede utilizar para modificar las propiedades de análisis deseadas de la capa de ruta, y la correspondiente capa puede se puede volver a resolver para determinar los resultados correspondientes. Se puede crear una nueva capa de ruta utilizando la herramienta de geoprocesamiento Hacer la capa de la ruta. Obtener el objeto RouteSolverProperties a partir de una nueva capa de ruta le permite volver a utilizar la capa existente para análisis posteriores en lugar de crear una nueva capa para cada análisis, que puede ser lento.

Después de modificar las propiedades del objeto RouteSolverProperties, la capa correspondiente se puede utilizar de inmediato con otras funciones y herramientas de geoprocesamiento. No es necesario actualizar o volver a cargar la capa para distinguir los cambios realizados a través del objeto.

Propiedades

PropiedadExplicaciónTipo de datos
accumulators
(Lectura y escritura)

Provides the ability to get or set a list of network cost attributes that are accumulated as part of the analysis. An empty list, [], indicates that no cost attributes are accumulated.

String
attributeParameters
(Lectura y escritura)

Provides the ability to get or set the parameterized attributes to be used in the analysis. The property returns a Python dictionary. The dictionary key is a two-value tuple consisting of the attribute name and the parameter name. The value for each item in the dictionary is the parameter value.

Parameterized network attributes are used to model some dynamic aspect of an attribute's value. For example, a tunnel with a height restriction of 12 feet can be modeled using a parameter. In this case, the vehicle's height in feet should be specified as the parameter value. If the vehicle is taller than 12 feet, this restriction will then evaluate to true, thereby restricting travel through the tunnel. Similarly, a bridge could have a parameter to specify a weight restriction.

Attempting to modify the attributeParameters property in place won't result in updated values. Instead, you should always use a new dictionary object to set values for the property. The following two code blocks demonstrate the difference between these two approaches.

#Don't attempt to modify the attributeParameters property in place.
#This coding method won't work.

solverProps.attributeParameters[('HeightRestriction', 'RestrictionUsage')] = "PROHIBITED"
#Modify the attributeParameters property using a new dictionary object.
#This coding method works. 

params = solverProps.attributeParameters
params[('HeightRestriction', 'RestrictionUsage')] = "PROHIBITED"
solverProps.attributeParameters = params
If the network analysis layer does not have parameterized attributes, this property returns None.

Dictionary
findBestSequence
(Lectura y escritura)

Controls whether the stops are reordered to find optimal routes. The following is a list of possible values:

  • FIND_BEST_ORDERThe stops will be reordered to find the optimal route. This option changes the route analysis from a shortest-path problem to a traveling salesperson problem (TSP). A value of True can also be used to specify this option.
  • USE_INPUT_ORDERThe stops will be visited in the input order. A value of False can also be used to specify this option.
String
impedance
(Lectura y escritura)

Provides the ability to get or set the network cost attribute used as impedance. This cost attribute is minimized while determining the best route.

String
orderingType
(Lectura y escritura)

Controls the ordering of stops when findBestSequence property is set to FIND_BEST_ORDER. The following is a list of possible values:

  • PRESERVE_BOTHPreserves the first and last stops by input order as the first and last stops in the route.
  • PRESERVE_FIRSTPreserves the first stop by input order as the first stop in the route, but the last stop is free to be reordered.
  • PRESERVE_LASTPreserves the last stop by input order as the last stop in the route, but the first stop is free to be reordered.
  • PRESERVE_NONEFrees both the first and last stop to be reordered.
String
outputPathShape
(Lectura y escritura)

Provides the ability to get or set the shape type for the route features that are output by the solver. The following is a list of possible values:

  • TRUE_LINES_WITH_MEASURESThe output routes will have the exact shape of the underlying network sources. Furthermore, the output includes route measurements for linear referencing. The measurements increase from the first stop and record the cumulative impedance to reach a given position.
  • TRUE_LINES_WITHOUT_MEASURESThe output routes will have the exact shape of the underlying network sources.
  • STRAIGHT_LINESThe output route shape will be a single straight line between the stops.
  • NO_LINESNo shape will be generated for the output routes.
String
restrictions
(Lectura y escritura)

Provides the ability to get or set a list of restriction attributes that are applied for the analysis. An empty list, [], indicates that no restriction attributes are used for the analysis.

String
solverName
(Sólo lectura)

Returns the name of the solver being referenced by the network analysis layer used to obtain the solver properties object. The property always returns the string value Route Solver when accessed from a RouteSolverProperties object.

String
timeOfDay
(Lectura y escritura)

Provides the ability to get or set the start date and time for the route. Route start time is mostly used to find routes based on the impedance attribute that varies with the time of the day. For example, a start time of 9 a.m. could be used to find a route that considers the rush-hour traffic. A value of None can be used to specify that no date and time should be used.

Instead of using a particular date, a day of the week can be specified using the following dates:

  • Hoy, 30/12/1899
  • Domingo, 31/12/1899
  • Lunes, 1/1/1900
  • Martes, 2/1/1900
  • Miércoles, 3/1/1900
  • Jueves, 4/1/1900
  • Viernes, 5/1/1900
  • Sábado, 6/1/1900

For example, to specify that the route should start at 5:00 p.m. on Tuesday, specify the value as datetime.datetime(1900, 1, 2, 17,0,0).

The timeZoneUsage parameter specifies whether the date and time refer to UTC or the time zone in which the first stop is located.

DateTime
timeZoneUsage
(Lectura y escritura)

Specifies the time zone of the timeOfDay parameter.

  • GEO_LOCALThe timeOfDay parameter refers to the time zone in which the first stop is located.
  • UTCThe timeOfDay parameter refers to Coordinated Universal Time (UTC). Choose this option if you want to solve the analysis for a specific time, such as now, but aren't certain in which time zone the facilities or demand points will be located.

When solving a route analysis that spans across multiple time zones and setting a start time, the orderingType cannot be set to PRESERVE_NONE. A starting location and time zone must be fixed.

String
uTurns
(Lectura y escritura)

Provides the ability to get or set the policy that indicates how the U-turns at junctions that could occur during network traversal between stops are being handled by the solver. The following is a list of possible values:

  • ALLOW_UTURNSU-turns are permitted at junctions with any number of connected edges.
  • NO_UTURNSU-turns are prohibited at all junctions, regardless of junction valency. Note, however, that U-turns are still permitted at network locations even when this setting is chosen; however, you can set the individual network locations' CurbApproach property to prohibit U-turns there as well.
  • ALLOW_DEAD_ENDS_ONLYU-turns are prohibited at all junctions, except those that have only one adjacent edge (a dead end).
  • ALLOW_DEAD_ENDS_AND_INTERSECTIONS_ONLYU-turns are prohibited at junctions where exactly two adjacent edges meet but are permitted at intersections (junctions with three or more adjacent edges) and dead ends (junctions with exactly one adjacent edge). Oftentimes, networks have extraneous junctions in the middle of road segments. This option prevents vehicles from making U-turns at these locations.
String
useHierarchy
(Lectura y escritura)

Controls the use of the hierarchy attribute while performing the analysis. The following is a list of possible values:

  • USE_HIERARCHY Use the hierarchy attribute for the analysis. Using a hierarchy results in the solver preferring higher-order edges to lower-order edges. Hierarchical solves are faster, and they can be used to simulate the preference of a driver who chooses to travel on freeways over local roads when possible—even if that means a longer trip. This option is applicable only if the network dataset referenced by the Network Analyst layer has a hierarchy attribute. A value of True can also be used to specify this option.
  • NO_HIERARCHYDo not use the hierarchy attribute for the analysis. Not using a hierarchy yields an exact route for the network dataset. A value of False can also be used to specify this option.
String
useTimeWindows
(Lectura y escritura)

Controls if time windows will be used at the stops. The following is a list of possible values:

  • USE_TIMEWINDOWSThe route will consider time windows on the stops. If a stop is arrived at before its time window, there will be wait time until the time window starts. If a stop is arrived at after its time window, there will be a time-window violation. Total time-window violation is balanced against minimum impedance when computing the route. This option is applicable only when the network cost attribute specified as the value for impedance property is in time units. A value of True can also be used to specify this option.
  • NO_TIMEWINDOWSThe route will ignore time windows on the stops. A value of False can also be used to specify this option.
String

Ejemplo de código

RouteSolverProperties example 1 (Python window)

The script shows how to update the impedance property to the TravelTime cost attribute, specify Minutes and Meters cost attributes as accumulative attributes, and use the current time as the route start time. It assumes that a route network analysis layer called Route has been created in a new map document based on the tutorial network dataset for San Francisco region.

#Get the route layer object from a layer named "Route" in the table of contents
routeLayer = arcpy.mapping.Layer("Route")

#Get the route solver properties object from the route layer
solverProps = arcpy.na.GetSolverProperties(routeLayer)

#Update the properties for the route layer using the route solver properties object
solverProps.impedance = "TravelTime"
solverProps.accumulators = ["Meters", "Minutes"]
#Only set the time component from the current date time as time of day
solverProps.timeOfDay = datetime.datetime.now().time()
RouteSolverProperties example 2 (workflow)

The script shows how to find a shortest (distance) and fastest (travel time) route between a set of stops and save each route as a feature class in a geodatabase. It illustrates how to create only one instance of a route layer and modify the impedance property using the RouteSolverProperties object to achieve the desired results.

import arcpy

#Set up the environment
arcpy.env.overwriteOutput = True
arcpy.CheckOutExtension("network")

#Set up variables
networkDataset = "C:/Data/SanFrancisco.gdb/Transportation/Streets_ND"
stops = "C:/Data/SanFrancisco.gdb/Analysis/Stores"
fastestRoute = "C:/Data/SanFrancisco.gdb/FastestRoute"
shortestRoute = "C:/Data/SanFrancisco.gdb/ShortestRoute"

#Make a new route layer using travel time as impedance to determine fastest route
routeLayer = arcpy.na.MakeRouteLayer(networkDataset, "StoresRoute",
                                     "TravelTime").getOutput(0)

#Get the network analysis class names from the route layer
naClasses = arcpy.na.GetNAClassNames(routeLayer)

#Get the routes sublayer from the route layer
routesSublayer = arcpy.mapping.ListLayers(routeLayer, naClasses["Routes"])[0]

#Load stops
arcpy.na.AddLocations(routeLayer, naClasses["Stops"], stops)

#Solve the route layer
arcpy.na.Solve(routeLayer)

#Copy the route as a feature class
arcpy.management.CopyFeatures(routesSublayer, fastestRoute)

#Get the RouteSolverProperties object from the route layer to modify the
#impedance property of the route layer.
solverProps = arcpy.na.GetSolverProperties(routeLayer)

#Set the impedance property to "Meters" to determine the shortest route.
solverProps.impedance = "Meters"

#Resolve the route layer
arcpy.na.Solve(routeLayer)

#Copy the route as a feature class
arcpy.management.CopyFeatures(routesSublayer, shortestRoute)

arcpy.AddMessage("Completed")

Temas relacionados

4/26/2014