サマリ
Provides access to analysis properties from a location-allocation network analysis layer. The GetSolverProperties function is used to obtain a LocationAllocationSolverProperties object from a location-allocation network analysis layer.
説明
The LocationAllocationSolverProperties object provides read and write access to all the analysis properties of a location-allocation network analysis layer. The object can be used to modify the desired analysis properties of the location-allocation layer, and the corresponding layer can be re-solved to determine the appropriate results. A new location-allocation layer can be created using the Make Location-Allocation Layer geoprocessing tool. Obtaining the LocationAllocationSolverProperties object from a new location-allocation layer allows you to reuse the existing layer for subsequent analyses rather than create a new layer for each analysis, which can be slow.
After modifying the properties on the LocationAllocationSolverProperties object, the corresponding layer can be immediately used with other functions and geoprocessing tools. There is no refresh or update of the layer required to honor the changes modified through the object.
特性
プロパティ | 説明 | データ タイプ |
accumulators (読み書き) | 解析時に累積されるネットワーク コスト属性のリストを取得または設定できます。空のリスト([])は、累積されるコスト属性がないことを表します。 | String |
attributeParameters (読み書き) | 解析で使用されるパラメータ化属性を取得または設定できます。プロパティは Python ディクショナリを返します。ディクショナリのキーは、属性名とパラメータで構成される 2 つの値の組み合わせです。ディクショナリ内の各アイテムの値はパラメータ値です。 パラメータ化されたネットワーク属性は、リアルタイムに変化する属性値をモデリングするために使用されます。たとえば、12 フィートの車高規制があるトンネルをパラメータを使用してモデリングできます。この場合、車両の高さ(フィート)をパラメータ値として指定する必要があります。車両の高さが 12 フィートを超えている場合は、この規制が true に評価され、トンネルの通行が規制されます。同様に、橋は重量規制を指定するパラメータを保持することができます。 attributeParameters プロパティを直接変更しようとしても、値は更新されません。常に新しいディクショナリ オブジェクトを使用して、プロパティの値を設定する必要があります。以下の 2 つのコード ブロックは、これらの 2 つの方法の違いを示しています。
| Dictionary |
defaultCapacity (読み書き) | Provides the ability to get or set the default capacity of facilities when the location-allocation problemType parameter is set to MAXIMIZE_CAPACITATED_COVERAGE. This parameter is ignored for all other problem types. Facilities have a Capacity property, which, if set to a nonnull value, overrides the defaultCapacity parameter for that facility. | Double |
facilitiesToFind (読み書き) | Provides the ability to get or set the number of facilities that the solver should locate. The property value is ignored if the problemType property is set to MINIMIZE_FACILITIES, since the solver determines the minimum number of facilities to locate to maximize coverage. The property value is also ignored if the problemType property is set to TARGET_MARKET_SHARE, because the solver searches for the minimum number of facilities required to capture the specified market share. | Integer |
impedance (読み書き) | Provides the ability to get or set the network cost attribute used as impedance. | String |
impedanceCutoff (読み書き) | Provides the ability to get or set the maximum impedance at which a demand point can be allocated to a facility. | Double |
impedanceParameter (読み書き) | Provides the ability to get or set a parameter value for the equations specified in the impedanceTransformation property. The property value is ignored when the impedanceTransformation property is set to LINEAR. The property value should not be zero. | Double |
impedanceTransformation (読み書き) | Provides the ability to get or set the equation for transforming the network cost between facilities and demand points. This property value, coupled with the impedanceParameter property value, specifies how severely the network impedance between facilities and demand points influences the solver's choice of facilities. The following is a list of possible values:
| String |
outputPathShape (読み書き) | Controls whether straight lines are used to represent the results from the location-allocation analysis. The following is a list of possible values:
| String |
problemType (読み書き) | Provides the ability to get or set the problem type that will be solved. The choice of the problem type depends on the kind of facility being located. Different kinds of facilities have different priorities and constraints. The following is a list of possible values:
| String |
restrictions (読み書き) | 解析時に適用される規制属性のリストを取得または設定できます。空のリスト([])は、解析で使用される規制属性がないことを表します。 | String |
solverName (読み取り専用) | Returns the name of the solver being referenced by the Network Analyst layer used to obtain the solver properties object. The property always returns the string value Location-Allocation Solver when accessed from a LocationAllocationSolverProperties object. | String |
targetMarketShare (読み書き) | Provides the ability to get or set the target market share in percentage to solve when the problemType property is set to TARGET_MARKET_SHARE. It is the percentage of the total demand weight that you want your solution facilities to capture. The solver chooses the minimum number of facilities required to capture the target market share specified by this numeric value. Any value set for facilitiesToFind property is ignored. | Double |
timeOfDay (読み書き) | Provides the ability to get or set the time and date of departure. The departure can be from facilities or demand points, depending on whether travel is from demand to facility or facility to demand. 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:
For example, to specify that the departure should occur at 8:00 a.m. on Friday, specify the value as datetime.datetime(1900, 1, 5, 8,0,0). The timeZoneUsage parameter specifies whether the date and time refer to UTC or the time zone in which the facilities or demand points are located. | DateTime |
timeZoneUsage (読み書き) | Specifies the time zone of the timeOfDay parameter.
When solving a location-allocation analysis that spans across multiple time zones, the following rules apply:
| String |
travelDirection (読み書き) | Controls the direction of travel between facilities and demand points when calculating the network costs. The following is a list of possible values:
| String |
useHierarchy (読み書き) | 解析を実行しているときの階層属性の使用を制御します。設定可能な値の一覧を次に示します。
| String |
uTurns (読み書き) | ストップ間のネットワーク移動中に発生する可能性のあるジャンクションでの U ターンを、解析でどのように処理するかを指定するポリシーを取得または設定できます。設定可能な値の一覧を次に示します。
| String |
メソッドの概要
メソッド | 説明 |
applyTravelMode (travel_mode) | Updates the analysis properties of a network analyst layer based on a travel mode object. The updated network analyst layer can then be solved to complete the analysis. |
メソッド
applyTravelMode (travel_mode)
パラメータ | 説明 | データ タイプ |
travel_mode | A variable that references a travel mode object derived from a network dataset. A list of travel mode objects can be obtained by calling the arcpy.na.GetTravelModes function. | Object |
When a network analyst layer is created, it is assigned default values for all of its analysis properties. The individual analysis properties can be updated using a solver properties object obtained from the network analyst layer. A travel mode stores a predefined set of analysis settings that help to perform a particular analysis, such as a walking time travel mode that stores the analysis settings required to perform a time-based walking analysis.
Using the applyTravelMode method, all the analysis settings that are defined in a travel mode can be applied at once. After the analysis properties are updated, the network analyst layer can be solved to complete the analysis.
If there is an error when updating the solver properties, such as when the provided travel mode references properties that don't exist on the current network dataset or references properties that are no longer applicable to the network dataset that was used to create the network analyst layer corresponding to the solver properties object, no exceptions are raised. The method will execute successfully, but you will get errors when you try to solve such a network analyst layer.
If the travel_mode parameter does not reference a travel mode object or a string, a TypeError exception is raised. If the travel_mode parameter references a string and the string cannot be internally converted to a valid string representation of a travel mode object, a ValueError exception is raised.
コードのサンプル
LocationAllocationSolverProperties example 1 (Python window)
The script shows how to update the problem type of a location-allocation network analysis layer to Minimize Facilities and set a power impedance transformation with an impedance parameter of 2. It assumes that a location-allocation layer called Stores Coverage has been created in a new map document based on the tutorial network dataset for San Francisco region.
#Get the location-allocation layer object from a layer named "Stores Coverage" in
#the table of contents
laLayer = arcpy.mapping.Layer("Stores Coverage")
#Get the solver properties object from the location-allocation layer
solverProps = arcpy.na.GetSolverProperties(laLayer)
#Update the properties for the location-allocation layer using the solver properties
#object
solverProps.problemType = "MINIMIZE_FACILITIES"
solverProps.impedanceTransformation = "POWER"
solverProps.impedanceParameter = 2
LocationAllocationSolverProperties example 2 (workflow)
The script shows how to choose optimal store locations that would generate the most business for a retail chain using location-allocation analysis. The script first creates a new location-allocation layer with appropriate analysis settings. As a next step, the candidate store locations and the block group centroids are loaded as facilities and demand points, respectively. The analysis is solved and saved to a layer file. Two subsequent analyses are performed by modifying the analysis properties using the LocationAllocationSolverProperties object. After each solve, the layer is stored as a layer file. The script uses the tutorial data for the San Francisco region. The detailed description of the scenario is available as part of exercise 9 in the Network Analyst tutorial. While the tutorial walks you through this scenario using the ArcMap user interface, the script provides an example of how the same scenario can be automated using a Python script.
import arcpy
#Set up the environment
arcpy.env.overwriteOutput = True
arcpy.env.workspace = "C:/data/SanFrancisco.gdb"
arcpy.CheckOutExtension("network")
#Set up variables
networkDataset = "Transportation/Streets_ND"
outNALayerName = "NewStoreLocations"
inFacilities = "Analysis/CandidateStores"
requiredFacility = "Analysis/ExistingStore"
competitorFacility = "Analysis/CompetitorStores"
inDemandPoints = "Analysis/TractCentroids"
outputFolder = "C:/data/output/"
#Create a new location-allocation layer. In this case the demand travels to
#the facility. We wish to find 3 potential store locations out of all the
#candidate store locations using the maximize attendance model.
outNALayer = arcpy.na.MakeLocationAllocationLayer(networkDataset, outNALayerName,
"TravelTime","DEMAND_TO_FACILITY",
"MAXIMIZE_ATTENDANCE",3,5,
"LINEAR")
#Get the layer object from the result object. The location-allocation layer
#can now be referenced using the layer object.
outNALayer = outNALayer.getOutput(0)
#Get the names of all the sublayers within the location-allocation layer.
subLayerNames = arcpy.na.GetNAClassNames(outNALayer)
#Stores the layer names that we will use later
facilitiesLayerName = subLayerNames["Facilities"]
demandPointsLayerName = subLayerNames["DemandPoints"]
#Load the candidate store locations as facilities using default search
#tolerance and field mappings.
arcpy.na.AddLocations(outNALayer, facilitiesLayerName, inFacilities, "", "",
exclude_restricted_elements = "EXCLUDE")
#Load the tract centroids as demand points using default search tolerance. Use
#the field mappings to map the Weight property from POP2000 field.
demandFieldMappings = arcpy.na.NAClassFieldMappings(outNALayer,
demandPointsLayerName)
demandFieldMappings["Weight"].mappedFieldName = "POP2000"
arcpy.na.AddLocations(outNALayer,demandPointsLayerName ,inDemandPoints,
demandFieldMappings, "",
exclude_restricted_elements = "EXCLUDE")
#Solve the location-allocation layer
arcpy.na.Solve(outNALayer)
#Save the solved location-allocation layer as a layer file on disk with
#relative paths
outLayerFile = outputFolder + outNALayerName + ".lyr"
arcpy.management.SaveToLayerFile(outNALayer,outLayerFile,"RELATIVE")
#We need to re-solve the previous scenario as a store-expansion scenario, in
#which we will start with an existing store and optimally locate two additional
#stores.
#Load the existing store location as the required facility. Use the field
#mappings to set the facility type to requried. We need to append this
#required facility to existing facilities.
fieldMappings = arcpy.na.NAClassFieldMappings(outNALayer, facilitiesLayerName)
fieldMappings["FacilityType"].defaultValue = 1
fieldMappings["Name"].mappedFieldName = "Name"
arcpy.na.AddLocations(outNALayer, facilitiesLayerName, requiredFacility,
fieldMappings, "", append = "APPEND",
exclude_restricted_elements = "EXCLUDE")
#Solve the location-allocation layer
arcpy.na.Solve(outNALayer)
#Save the solved location-allocation layer as a layer file on disk with
#relative paths
updatedNALayerName = "StoreExpansionScenario"
outNALayer.name = updatedNALayerName
outLayerFile = outputFolder + updatedNALayerName + ".lyr"
arcpy.management.SaveToLayerFile(outNALayer,outLayerFile,"RELATIVE")
#We need to resolve the previous scenario and locate new stores to
#maximize market share in light of competing stores.
#Load the competitor store locations as the competitor facilities. Use the field
#mappings to set the facility type to Competitor. We need to append these
#competitor facilities to existing facilities.
fieldMappings["FacilityType"].defaultValue = 2
arcpy.na.AddLocations(outNALayer, facilitiesLayerName, competitorFacility,
fieldMappings, "", append = "APPEND",
exclude_restricted_elements = "EXCLUDE")
#Get the LocationAllocationSolverProperties object from the location-allocation
#layer to modify the analysis settings for the layer.
solverProps = arcpy.na.GetSolverProperties(outNALayer)
#Set the problem type to Maximize Market Share, and impedance transformation to
#Power with an impedance parameter value of 2.
solverProps.problemType = "MAXIMIZE_MARKET_SHARE"
solverProps.impedanceTransformation = "POWER"
solverProps.impedanceParameter = 2
#Solve the location-allocation layer
arcpy.na.Solve(outNALayer)
#print the market share that was obtained
arcpy.AddMessage(arcpy.GetMessage(0))
#Change the name of the NA Layer
updatedNALayerName = "MaximizedMarketShareStoreLocations"
outNALayer.name = updatedNALayerName
#Save the solved location-allocation layer as a layer file on disk with
#relative paths
outLayerFile = outputFolder + updatedNALayerName + ".lyr"
arcpy.management.SaveToLayerFile(outNALayer,outLayerFile,"RELATIVE")
arcpy.AddMessage("Completed")
ApplyTravelMode example 3 (workflow)
This script shows how to find the best facility locations based on a Trucking Time travel mode.
#Import modules
import os
import arcpy
#Define variables
workspace = "C:/data/SanDiego.gdb"
output_folder = "C:/data/output"
nds = os.path.join(workspace, "Transportation", "Streets_ND")
facilities = os.path.join(workspace, "Warehouses")
demand_points = os.path.join(workspace, "TruckDepots")
analysis_layer_name = "NewWarehouseLocation"
#Set environment variables
arcpy.env.overwriteOutput = True
#Check out the network analyst extension
arcpy.CheckOutExtension("network")
#Create a new closest facility analysis layer
make_layer_result = arcpy.na.MakeLocationAllocationLayer(nds, analysis_layer_name,
"TravelTime")
analysis_layer = make_layer_result.getOutput(0)
#Add facilities and demand points to the analysis layer using default field mappings
sub_layer_names = arcpy.na.GetNAClassNames(analysis_layer)
facility_layer_name = sub_layer_names["Facilities"]
demand_points_layer_name = sub_layer_names["DemandPoints"]
arcpy.na.AddLocations(analysis_layer, facility_layer_name, facilities, "#", "#")
arcpy.na.AddLocations(analysis_layer, demand_points_layer_name, demand_points ,
"#", "#")
#Get the Trucking Time travel mode from the network dataset
travel_modes = arcpy.na.GetTravelModes(nds)
trucking_mode = travel_modes["Trucking Time"]
#Apply the travel mode to the analysis layer
solver_properties = arcpy.na.GetSolverProperties(analysis_layer)
solver_properties.applyTravelMode(trucking_mode)
#Solve the analysis layer and save the result as a layer file
arcpy.na.Solve(analysis_layer)
output_layer = os.path.join(output_folder, analysis_layer_name + ".lyr")
arcpy.management.SaveToLayerFile(analysis_layer, output_layer, "RELATIVE")
arcpy.AddMessage("Completed")