JP2012098128A - In-vehicle navigation device, control method for in-vehicle navigation device and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable facilities to be properly searched according to a traveling state of a vehicle when a driver searches facilities located in the vicinity of a route to a destination.SOLUTION: An in-vehicle navigation device 1 capable of searching a route to a destination comprises: a route side facilities search function for searching facilities located in a predetermined searching range from the route to the destination; and a control unit 10 for, when executing the route side facilities search function, executing a search of facilities after adjusting size of the searching range based on congestion information concerning the route to the destination.

Description

  The present invention relates to an in-vehicle navigation device capable of searching for a route to a destination, a control method for the in-vehicle navigation device, and a program for controlling the in-vehicle navigation device.

2. Description of the Related Art Conventionally, an in-vehicle navigation device that searches not only for facilities located around a host vehicle but also for facilities located around a route to a destination is known. (For example, refer to Patent Document 1).
In this type of in-vehicle navigation, when searching for facilities located around the route to the destination, the search range is determined in advance, such as searching for facilities whose shortest distance from the route is within 5 km. A facility belonging to the range is searched.

JP-A-2005-195406

By the way, when a vehicle is involved in a traffic jam or a traffic jam occurs on a road where the facility is in contact, if you go through a facility far away, there will be a significant time loss until you reach the destination. Because of this possibility, there are many cases where you do not want to go through facilities as far away as possible under these circumstances. However, in the above-described navigation device, when searching for facilities located around the route to the destination, the facility is searched within a predetermined search range regardless of the traveling state of the vehicle. From the results, it was necessary to further narrow down the facilities that could be routed according to the driving situation of the vehicle.
The present invention has been made in view of the above-described circumstances, and an object thereof is to provide an in-vehicle navigation device capable of appropriately searching for facilities along a route to a destination according to a traveling state of a vehicle.

  In order to achieve the above object, the present invention provides an in-vehicle navigation device capable of searching for a route to a destination, a route side facility search function for searching for a facility located in a predetermined search range from the route to the destination, A control unit that, when executing the route side facility search function, adjusts the size of the search range based on traffic jam information related to a route to a destination, and executes a facility search. To do.

  Here, in the in-vehicle navigation device according to the invention, the control unit adjusts the size of the search range based on traffic jam information of an area including a route to the destination when the route side facility search function is executed. Then, the facility search may be executed.

  Further, in the in-vehicle navigation device according to the above invention, the control unit, when executing the route side facility search function, the more the road belonging to the area including the route to the destination is congested, the more the search range On the other hand, the facility search may be executed after the search range is widened so as not to be congested.

  The vehicle-mounted navigation device according to the invention further includes a display unit capable of displaying a map, and the control unit provides a route to a destination for each area divided on the map when the route side search function is executed. The facility is searched after adjusting the size of the search range based on the traffic jam information, and each area on the map is displayed on the display unit in a manner in which the degree of traffic jam for each area can be understood. The facility search results in each area may be displayed.

  In the in-vehicle navigation device of the above invention, the traffic jam information related to the route to the destination may be information generated based on information related to traffic jams on the past roads.

  In order to achieve the above object, the present invention controls a vehicle-mounted navigation device capable of searching for a route to a destination, and searches for a facility located in a predetermined search range from the route to the destination. When executing the facility search function, the size of the search range is adjusted based on the traffic jam information related to the route to the destination, and the facility search is executed.

  In order to achieve the above object, the present invention provides a computer-readable program for controlling an in-vehicle navigation device capable of searching for a route to a destination. Control for executing facility search after adjusting the size of the search range based on traffic jam information related to the route to the destination when executing the route side facility search function for searching for facilities located in the search range It functions as a part.

  According to the present invention, when searching for facilities located around a route to a destination, it is possible to appropriately search for facilities according to the traveling state of the vehicle.

It is a block diagram which shows the functional structure of the vehicle-mounted navigation apparatus which concerns on this embodiment. It is the figure which specified the area on the map. It is a figure which shows the data structure of a traffic jam information database. It is a flowchart which shows operation | movement of a vehicle-mounted navigation apparatus. It is a figure which shows an example of the map displayed on the display part. It is a figure which shows a facility and a recommended route typically. It is a figure which shows the data structure of a search distance database. It is a figure which shows an example of the display part on which the search result was displayed.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a functional configuration of an in-vehicle navigation device 1 according to the present embodiment.
As shown in this figure, the in-vehicle navigation device 1 includes a control unit 10, an absolute position and direction detection unit 11, a relative direction detection unit 12, a vehicle speed detection unit 13, an FM multiple reception processing unit 14, and a beacon reception process. Unit 15, display unit 16, input unit 17, user interface unit 18, recording device control unit 19, external recording device control unit 20, voice recognition control unit 21, and telephone control unit 22. ing.

  The control part 10 controls the vehicle-mounted navigation apparatus 1 whole, and is comprised from CPU and its peripheral circuit. The ROM 30 stores a BIOS, a boot program, other control programs, and the like in advance, and is accessed by the CPU when the in-vehicle navigation device 1 is activated. The CPU of the control unit 10 reads out a control program or the like stored in the ROM 30 and controls each unit of the in-vehicle navigation device 1. The DRAM 31 is a memory used for the work area of the CPU. The SRAM 32 is backed up by a battery or the like and retains the memory contents even when the main power source of the in-vehicle navigation device 1 such as a vehicle accessory power source is off. The VRAM 33 is a memory in which display data for the display unit 16 described later is stored.

The absolute position and direction detection unit 11 calculates the absolute position coordinates and direction on the ground surface for the current position of the vehicle on which the in-vehicle navigation device 1 is mounted, that is, the position of the host vehicle. Is received by the GPS antenna 11a or a receiver, and absolute position coordinates and azimuth on the ground surface are calculated from the GPS signal superimposed on the GPS radio wave and output to the control unit 10.
The relative azimuth detection unit 12 detects the relative azimuth of the vehicle position using a gyro sensor or the like, and outputs the detected relative azimuth to the control unit 10.
The vehicle speed detection unit 13 calculates the vehicle speed based on the vehicle speed pulse obtained from the vehicle and outputs the vehicle speed to the control unit 10 in order to calculate the vehicle speed. The control unit 10 detects the speed of the vehicle based on the detection value of the vehicle speed detection unit 13.

The FM multiplex reception processing unit 14 receives FM multiplex broadcast waves under the control of the control unit 10, extracts information such as road traffic information included in the FM multiplex broadcast waves, and outputs the information to the control unit 10. is there. Specifically, the FM multiplex reception processing unit 14 includes an FM multiplex dedicated tuner and a multiplex encoder. When receiving the FM multiplex broadcast, the FM multiplex dedicated tuner outputs an FM multiplex signal to the multiplex encoder. The multiplex encoder decodes the FM multiplex signal input from the FM multiplex dedicated tuner, acquires information such as road traffic information, and outputs the information to the control unit 10.
The beacon reception processing unit 15 receives radio waves related to information such as road traffic information emitted by beacons provided on the road under the control of the control unit 10 and outputs the received radio waves to the control unit 10.

The display unit 16 includes a display panel such as a liquid crystal display panel, and displays various types of information such as a map for navigation and an operation menu on the display panel under the control of the control unit 10.
The input unit 17 includes a plurality of operation buttons and a touch panel disposed on the display panel of the display unit 16, detects user operation buttons and operations on the touch panel, and outputs them to the control unit 10. The input unit 17 may include a remote controller.
The user interface unit 18 is an I / O control circuit, a driver, or the like, and is an interface that connects the display unit 16 and the input unit 17 to the control unit 10.

The recording device control unit 19 is connected to a hard disk 25 that stores various data, and reads / writes data from / to the hard disk 25 under the control of the control unit 10.
Various data stored in the hard disk 25 includes at least map data 40, route search data 41, a traffic jam information database 42, and a search distance database 43. The search distance database 43 will be described later.
The map data 40 is data relating to a map. When displaying the current position of a vehicle or when guiding a route, display data displayed on the display panel of the display unit 16, roads, stores, and facilities on the map are displayed. It contains data related to such information. The map data 40 includes location information of each of the facilities that can be selected by the user at least when the route side facility search function described later is executed.
The route search data 41 includes link data related to section routes (links) divided in predetermined units and node data related to intersections (nodes). The link data and the node data include road type, road width, number of lanes, one-way traffic information, speed limit information, and link cost data indicating the link cost of each link. The link cost of each link is calculated from the link length, link type, average travel time, and the like.
The traffic jam information database 42 is a database that stores an area and traffic jam information of roads belonging to the area in association with each other.

FIG. 2 is a diagram clearly showing areas on a map in order to explain the concept of areas in the present embodiment.
An area is one area that can be created when the maps are divided so as not to overlap. In the present embodiment, as shown in FIG. 2, the map is divided into a lattice pattern by a longitude line shifted by a predetermined value and a latitude line shifted by a predetermined value, and the longitude line and the latitude line An area is assigned to each of the enclosed rectangular areas.

As described above, in the present embodiment, in the traffic jam information database 42, for each area, the area and road congestion information belonging to the area are stored in association with each other.
The traffic congestion information of roads belonging to an area refers to information indicating the tendency of traffic congestion of a road located in the area for a certain area. “Traffic is too large” to indicate that traffic is in a traffic jam, “Traffic is heavy” indicating that traffic is not congested but is not free, and certain sections are congested and congested There are three “small traffic jams” indicating that the vehicle tends to travel smoothly.

Whether a certain area is set to “large traffic jam”, “medium traffic jam”, or “small traffic jam” is determined by the following method.
That is, the road traffic information acquired by the FM multiplex reception processing unit 14 and the beacon reception processing unit 15 includes at least congestion information and section travel time information.
The congestion information is information indicating the degree of congestion of vehicles in a section from one point on the road to another point. In this embodiment, a certain section is congested, and the section “Congestion” indicating that the vehicle is not able to travel smoothly, “Congestion” indicating that there is no traffic congestion in a certain section, but the section is not free, and traffic congestion and congestion in a certain section There are three pieces of information indicating “smooth” indicating that the vehicle can travel smoothly.
The section travel time information is information indicating the required travel time from one point on the road to another point.
Then, each time the road traffic information is acquired, the control unit 10 extracts the congestion state information and the section travel time information, and stores these information in the hard disk 25 in association with the information indicating the road. And the control part 10 calculates the degree of the traffic congestion of the road contained in each area for every area based on the congestion condition information memorize | stored in the memory | storage in the hard disk 25, and area travel time information, and is based on the calculated degree. Based on this, “large traffic jam”, “medium traffic jam”, and “small traffic jam” are determined for each area.

An example of the calculation of the degree of congestion will be described with reference to a specific example. The control unit 10 calculates the average of each road based on past congestion information of a road in the area for a certain area. A state, that is, whether it is “congested”, “congested”, or “smooth” on average is calculated using an average formula. Then, when each road in a certain area is “congested” on average, the control unit 10 sets the area as “congested”, and these roads are “congested” on average. If there is, the area is set as “congested”, and if each of these roads is “smooth” on average, the area is set as “small traffic”.
For example, referring to FIG. 2, road R1 and road R3 are present in area C1 in FIG. When setting the traffic jam information for the area C1, the control unit 10 calculates an average traffic jam state for the portion included in the area C1 of the road R1 based on the congestion information stored in the hard disk 25. The average congestion state is calculated for the portion included in the area C1 of the road R3, and the congestion of the area C1 is calculated based on the average state of the road R1 and the average state of the road R3. Set the information.

In the above example, the traffic congestion information is set for each area after using the average formula based on the congestion condition information. However, the method for setting the traffic congestion information for the area is not limited to this. For example, when using the average formula, the degree of traffic congestion may be calculated after weighting so that the new congestion degree information is reflected in the calculation result of the traffic congestion degree.
Further, the degree of traffic jam on the road included in the area may be estimated using the section travel time information, and the traffic jam information may be set based on this estimation.
Further, the degree of traffic jam may be calculated using other statistical methods such as variance and deviation, and the traffic jam information may be set based on the calculation result.
In the above example, the congestion information is set for the area based on the congestion information included in the road traffic information and the section travel time information. For example, the telephone control unit 22 described later is controlled. Thus, information related to road traffic jams may be acquired from an external server on the Internet, and traffic jam information may be set for an area based on the acquired information.
In addition, when a recording medium such as a CD-ROM or DVD-ROM in which information relating to road traffic jams is stored and distributed, information relating to road traffic jams is read by reading these recording media. And traffic congestion information of the area may be set based on the acquired information.
In the above example, the area is a rectangular area surrounded by a predetermined latitude line and a predetermined longitude line, but the form and shape of the area are not limited thereto. An appropriate form and shape can be obtained according to the shape of the road, topography, geography, and the like. In this case, for example, each area may be defined by polygon data (data indicating a polygonal area defined by connecting a plurality of points indicated by coordinate values including longitude and latitude).
In the present embodiment, the hard disk 25 is connected to the recording device control unit 19, but another non-volatile memory such as an EEPROM may be connected.
In this embodiment, map data and route search data are stored in the hard disk 25. However, a CD-ROM or DVD-ROM storing these data is read by a dedicated optical disk drive. Also good.

FIG. 3 is a diagram schematically showing the data structure of the traffic jam information database 42.
As shown in FIG. 3, the traffic jam information database 42 stores areas and traffic jam information in association with each other.
Note that these pieces of information may be stored in association with each other by time. In many cases, the situation of traffic jams varies depending on the time zone. By storing the areas and the traffic jam information in association with each other according to the time zones, the traffic jam information can be set for the areas in accordance with the reality.

Returning to FIG. 1, the external recording device control unit 20 records / reads data to / from an external recording medium connected to the in-vehicle navigation device 1 under the control of the control unit 10. Examples of the external recording medium include a Memory Stick (registered trademark), a memory card, a CF card (registered trademark), and a USB memory.
The voice recognition control unit 21 includes a microphone (not shown) for a user to input voice, recognizes a command input by voice through the microphone, and outputs the recognition result to the control unit 10.
The telephone control unit 22 performs wireless communication conforming to a predetermined short-range wireless communication standard with the mobile phone under the control of the control unit 10, and the mobile phone receives an incoming call received from a fixed phone or another mobile phone. When a voice is received and a voice signal indicating the received voice is output to the control unit 10 and a voice signal related to a transmission voice uttered by the user is input from the control unit 10, the transmission indicated by the voice signal Send audio to mobile phone.
Furthermore, in the present embodiment, the mobile phone controlled by the telephone control unit 22 can access a predetermined external server on the Internet via the telephone line network to which the wireless base station is connected and the Internet. The telephone control unit 22 can access a predetermined external server on the Internet via a mobile phone.

The in-vehicle navigation device 1 configured as described above has a route search function.
In the route search function, when a search for a route to the destination is instructed by the operation button of the input unit 17 or the touch panel, the control unit 10 searches for a recommended route to the destination. In the present embodiment, the control unit 10 basically sets, as a recommended route, a route that minimizes the sum of the link costs of each link in a continuous link to the destination based on route search data. Explore. After searching for the recommended route, the control unit 10 clearly indicates the current position of the vehicle and the route on which the vehicle should travel on the map displayed on the display panel of the display unit 16, and notifies the driver of the vehicle. Route guidance. During route guidance, the control unit 10 corrects the vehicle position calculated by the autonomous navigation based on the detection values of the relative direction detection unit 12 and the vehicle speed detection unit 13 with the vehicle position detected by the absolute position direction detection unit 11. By using hybrid navigation, the vehicle position obtained with high accuracy is displayed on a map and route guidance is performed.

Furthermore, the in-vehicle navigation device 1 according to the present embodiment has a route side facility search function.
This route side facility search function assumes that a route from the vehicle position to the destination has been searched by the route search function described above, and a specific facility (gas station) existing along the route to the destination. And a convenience store).
Hereinafter, the operation of the in-vehicle navigation device 1 when the route side facility search function is executed will be described in detail using a flowchart.

FIG. 4 is a flowchart showing the operation of the in-vehicle navigation device 1 when the route side facility search function is executed.
As a premise of the flowchart shown in this figure, a recommended route from the vehicle position to the destination is already searched by the route search function, and route guidance is performed according to the searched recommended route, and the user It is assumed that the vehicle is running based on the guidance.

The control unit 10 of the in-vehicle navigation device 1 monitors whether or not the execution of the route side facility search function is instructed (step SA1).
In the present embodiment, the execution instruction of the route side facility search function in step SA1 is performed as follows. First, the user operates the operation buttons and the touch panel to display a dedicated screen for instructing execution of the route side facility search function on the display unit 16. On this screen, at least a list of types of facilities that can be searched (eg, gas stations, convenience stores, bookstores, predetermined public facilities, police stations) is displayed in a selectable manner, and for instructing the start of the search. The button is displayed so as to be touch-operable, and the user instructs the execution of the route side facility search function by touching the button for instructing the search start after selecting the type of facility to be searched. That is, in step SA1, at least the type of facility to be searched is specified, and the start of execution of the route side facility search function is instructed.

When execution of the route side facility search function is instructed (step SA1: YES), the control unit 10 includes all links from the current vehicle position to the destination on the recommended route searched by the route search function. Is acquired (step SA2).
Next, the control unit 10 sets a link corresponding to the road on which the host vehicle is traveling among the links acquired in step SA2 as a processing target link (step SA3). As described above, the recommended route is represented by a continuous link, but hereinafter, the processing of step SA6 to step SA12 is executed in order from the vehicle position to the destination for each link. It will be. That is, “set as a processing target link” means that one certain link is set as a link to be processed in steps SA6 to SA12.

Next, the control unit 10 resets the number of search facilities (step SA4).
Here, the number of search facilities is the total number of facilities searched as facilities existing along the recommended route (route to the destination) as a result of executing the route side facility search function. In the present embodiment, the upper limit of the number of facilities that can be searched by the route side facility search function is determined in advance, and when the number of search facilities reaches the upper limit, the search for further facilities is stopped. In step SA4, for example, a process of setting the value of a variable defined in the program as a variable for storing data indicating the number of search facilities to “0” is performed.

Next, the control unit 10 determines whether or not the processing has been completed for all the continuous links related to the recommended route, and the number of search facilities has not reached the upper limit value (step SA5). ). With this determination, the following processing from step SA6 to step SA12 is performed for each link for all links.
If this is the case (step SA5: YES), the control unit 10 acquires an area that belongs to the recommended route corresponding to the link that is the processing target in step SA3 and that exists around the recommended route ( Step SA6). Here, the operation of step SA6 will be described in detail.

FIG. 5 is a diagram illustrating an example of a map displayed on the display unit 16 in order to explain the operation of step SA6.
In FIG. 5, as a result of searching for a route to the destination DN, a route indicated by a thick line on the road R1 is searched as a recommended route, and the route is guided so that the vehicle travels on the recommended route. Shall. Furthermore, as shown by a dotted line surrounding the recommended route in FIG. 5, this recommended route is assumed to be a route in which the link L1, the link L2, and the link L3 are continuously formed. In FIG. 5, the own vehicle position mark 60 is a mark indicating the position of the own vehicle on the map, and the vehicle is located on the road R1 at the position indicated by the own vehicle position mark 60 and on the road R1. It is assumed that the vehicle is traveling in the direction of arrow Y1.
As described above, in step SA6, the control unit 10 acquires a recommended route corresponding to the link set as the processing target link in step SA3 and an area existing around the recommended route. Here, the area existing around the recommended route corresponding to the link set as the processing target link in step SA3 is an area where the facility along the recommended route may be searched. Although details will be described later in this embodiment, since a facility whose shortest distance from the recommended route is within 300 m may be searched as a facility along the recommended route, the separation distance from the recommended route is within 300 m. This area corresponds to an area existing around the recommended route.
As an example of the process in step SA6, referring to FIG. 5, when the link to be processed is the link L1, the control unit 10 includes areas A4, A3, A3, which are areas to which the recommended route corresponding to the link L1 belongs. Then, the area B3 is acquired, and the area B4 (the distance between the area B4 and the recommended path corresponding to the link L1 is within 300 m) is acquired as an area existing around the recommended path. .

Next, the control unit 10 refers to the traffic jam information database 42 and acquires the traffic jam information of each area acquired in step SA6 (step SA7). Assuming that area A4, area A3, area B3, and area B4 are acquired in step SA6, referring to FIG. 3, “congested” is the traffic information of area A4, and “congested” is the traffic information of area A3. ”Is acquired as“ congestion large ”as the traffic information of area B3 and“ small traffic ”is acquired as the traffic information of area B4.
Next, the control unit 10 sets a search distance (search range) for each area acquired in step SA6 (step SA8). Here, the process of step SA8 will be described in detail together with the concept of the search distance.

FIG. 6 is a diagram schematically showing a facility and a recommended route in order to explain the processing in step SA8.
In the present embodiment, the map data 40 is referred to when searching for a facility that exists along a recommended route, the facility located in each area is identified for each area, and the recommended route from the facility is identified for each identified facility. The shortest distance to (see FIG. 6) is calculated. Then, the calculated shortest distance is compared with the search distance. When the calculated shortest distance is shorter than the search distance, the facility is searched as a facility existing along the recommended route, while the calculated distance is calculated. If the shortest distance is long, the facility is not searched. That is, the search distance is a value that serves as a reference for determining whether or not the facility exists along the recommended route when searching for the facility along the recommended route.
In step SA8, the control unit 10 refers to the search distance database 43 and sets the search distance for each area according to the traffic jam information set in each area.

FIG. 7 is a diagram schematically showing the data structure of the search distance database 43.
As shown in FIG. 7, the search distance database 43 stores traffic jam information and the search distance in association with each other. In this embodiment, “large traffic jam” and a search distance of 50 m are stored in association with each other, and in step SA8, the control unit 10 sets 50 m as the search distance for the “large traffic jam” area. The search distance database 43 stores “congested” and the search distance 150 m in association with each other. In step SA 8, the control unit 10 sets 150 m as the search distance for the “congested” area. To do. In the search distance database 43, “small traffic jam” is stored in association with the search distance of 300 m. In step SA8, the control unit 10 sets 300 m as the search distance for the “small traffic jam” area. To do.
As described above, in this embodiment, the relationship between the traffic information and the search distance is defined so that the search distance of the “congestion large” area is the shortest and the search distance of the “congestion small” area is the longest. However, the reason for this will be described later.

  After setting the search distance for each area acquired in step SA6, the control unit 10 sets the shortest distance to the recommended route corresponding to the link set as the processing target in step SA3 for each area. A facility that is less than the search distance is searched (step SA9).

Here, the process of step SA9 will be described with an example.
For example, referring to FIG. 3, it is assumed that the relationship between the area and the traffic jam information in the traffic jam information database 42 is as shown in FIG. It is assumed that the link to be processed in step SA3 is the link L1. In this case, the areas acquired in step SA6 are area A4, area A3, area B3, and area B4. Furthermore, as shown in FIG. 3, area A4 is set as “congested” as traffic jam information. 150 m is set as the search distance, “medium traffic” is set as the traffic information for the area A3, 150 m is set as the search distance for the area A3, and “large traffic jam” is set as the traffic information for the area B3. Is set to 50 m, and in area B4, “small traffic jam” is set as traffic jam information, and 300 m is set as the search distance.
Under such circumstances, in step SA9, the control unit 10 searches for a facility where the shortest distance to the recommended route corresponding to the link L1 is less than the search distance set for each area for each area.

  Specifically, the control unit 10 recommends a facility having a shortest distance to the recommended route corresponding to the link L1 within 150 m (= search distance set in the area A4) for the facility located in the area A4. Search for facilities along the route. Similarly, for the facility located in the area A3, the control unit 10 searches for a facility whose shortest distance to the recommended route is 150 m (= search distance set in the area A3) as a facility along the recommended route. . In addition, for the facility located in the area B3, the control unit 10 searches for a facility whose shortest distance to the recommended route is within 50 m (= search distance set in the area B3) as a facility along the recommended route. In addition, for the facility located in the area B4, the control unit 10 searches for a facility whose shortest distance to the recommended route is within 300 m (= search distance set in the area B4) as a facility along the recommended route.

In this manner, after the facilities existing along the recommended route are searched for the recommended route corresponding to the link set as the processing target link in step SA3, the control unit 10 actually searches for the facility. If the facility is actually searched (step SA10: YES), the number of searched facilities is increased by the number of searched facilities (step SA11), and the facility is not searched. In the case (step SA10: NO), the processing procedure proceeds to step SA12.
In step SA12, the control unit 10 sets the processing target link as the next link, and returns the processing procedure to step SA5.

  As described above, in this embodiment, the relationship between the traffic information and the search distance is defined so that the search distance of the “congestion large” area is the shortest and the search distance of the “congestion small” area is the longest. Has been. In other words, for a certain area, the search distance is set shorter as the road belonging to the area tends to be congested, and conversely, the search distance is set as the road belonging to the area tends not to be congested. Is set longer. By doing so, the following effects can be obtained.

In other words, when a vehicle is traveling on a road belonging to a certain area and the road belonging to the area tends to be congested, the user who drives the vehicle needs to go through some facility. Even if a request to go through is made, it is assumed that there are few people who want to go through a facility located away from the current location. Because the roads belonging to the area are congested, it means that the roads in the area corresponding to the area are crowded. This is because there may be a case where it does not go smoothly due to the above, and a large time loss may occur.
On the other hand, when the vehicle is traveling on a road belonging to one area and the road belonging to the area tends not to be congested, the user who drives the vehicle may need to go through some facility. It is assumed that even when a facility is generated and a request to go through is generated, even if the facility is located relatively far from the current location, the user wants to go through the facility. This is because the roads belonging to the area are not congested means that the roads in the area corresponding to the area are not crowded, even if the road is located via a facility located relatively far away. This is because the facility can be reached smoothly and no significant time loss occurs.

Based on this, in the present embodiment, for a certain area, the search distance is set shorter as the road belonging to the area tends to be congested. This prevents a facility located relatively far away from being searched as a facility along the recommended route in an area where the road tends to be congested. This eliminates the need for the user to search for a facility located relatively close to the current location so as not to cause much time loss among the searched facilities, improving user convenience and operability. Can be improved. In addition, it is possible to reliably prevent a situation in which a user mistakenly selects a facility located relatively far from the current location as a passing facility, resulting in a large time loss.
Further, in the present embodiment, for a certain area, the search distance is set to be longer as the road belonging to the area tends not to be congested. As a result, in an area where roads tend not to be congested, even facilities located relatively far away are searched as facilities existing along the recommended route. This prevents the options from being narrowed unnecessarily, improving the convenience for the user.

  Now, referring back to FIG. 4 above, when the processing is completed for all the continuous links related to the recommended route in step SA5 or the number of search facilities reaches the upper limit (step SA5: NO), the control unit 10 Displays the processing result on the display unit 16 (step SA13).

FIG. 8 is a diagram illustrating an example of a screen displayed on the display unit 16 in step SA13.
As shown in FIG. 8, the searched facility is directly displayed on the map as a search result. Thereby, the relative position of the facility on the map is intuitively grasped by the user.
Also, on the map, you can clearly see the area where “Congestion is high”, the area where “Congestion is”, and the area where “Congestion is low” are set. It has become. In the example of FIG. 8, the background color is lightly displayed in the order of “large traffic jam”, “medium traffic jam”, and “small traffic jam”. As a result, the user can sensuously recognize the traffic jam information for each area in the recommended route, and can appropriately select the facility to be routed based on this recognition.
Further, for each searched facility, a list of the facility name, the shortest distance to the recommended route, and whether the facility is located on the right side or the left side with respect to the traveling direction is displayed. Thereby, the user can acquire useful information in selecting the facility through which the user passes.
It should be noted that the mark indicating the facility on the map and each record in the list can be touch-operated, and triggered by the touch operation to the destination via the facility selected by the touch operation. The recommended route to reach is re-searched, and the search result is displayed on the map.

As described above, according to the present embodiment, the control unit 10 includes a route side facility search function for searching for a facility located at a predetermined search distance (search range) from a recommended route (route to the destination). When executing this function, the facility is searched after adjusting the size of the search distance based on the traffic jam information related to the recommended route.
According to this, it is possible to appropriately adjust the facility searched as the facility existing along the recommended route according to the traffic jam situation of the route to the destination, that is, according to the traveling state of the vehicle.

Moreover, in this embodiment, the control part 10 performs the search of a facility after adjusting the magnitude | size of search distance based on the traffic congestion information of the area where a recommended route is included at the time of execution of a route side facility search function. .
According to this, it is possible to appropriately adjust the facility searched as the facility existing along the recommended route according to the traveling state of the vehicle, based on the traffic congestion information of the area to which the recommended route belongs. Become.

In the present embodiment, when the route side facility search function is executed, the control unit 10 narrows the search distance as the road belonging to the area including the recommended route is congested. The facility search is performed after the search distance is increased as much as possible.
Specifically, in the present embodiment, the relationship between the traffic information and the search distance is defined so that the search distance of the “large traffic jam” area is the shortest and the search distance of the “small traffic jam” area is the longest. Has been. In other words, for a certain area, the search distance is set shorter as the road belonging to the area tends to be congested, and conversely, the search distance is set as the road belonging to the area tends not to be congested. Is set longer. By doing so, the following effects can be obtained.
In other words, when a vehicle is traveling on a road belonging to a certain area and the road belonging to the area tends to be congested, the user who drives the vehicle needs to go through some facility. Even if a request to go through is made, it is assumed that there are few people who want to go through a facility located away from the current location. Because the roads belonging to the area are congested, it means that the roads in the area corresponding to the area are crowded. This is because there may be a case where it does not go smoothly due to the above, and a large time loss may occur.
On the other hand, when the vehicle is traveling on a road belonging to one area and the road belonging to the area tends not to be congested, the user who drives the vehicle may need to go through some facility. It is assumed that even when a facility is generated and a request to go through is generated, even if the facility is located relatively far from the current location, the user wants to go through the facility. This is because the roads belonging to the area are not congested means that the roads in the area corresponding to the area are not crowded, even if the road is located via a facility located relatively far away. This is because the facility can be reached smoothly, and a large time loss cannot occur.

In the present embodiment, the control unit 10 adjusts the size of the search distance for each area divided on the map based on the traffic jam information related to the recommended route when the route side search function is executed. In addition, the display unit 16 displays each area on the map in a manner in which the degree of traffic jam for each area is known, and then displays the result of the facility search in each area.
Specifically, as shown in FIG. 8, on the map, an area in which “large traffic jam” is set as traffic jam information, an area in which “medium traffic jam” is set, and “small traffic jam” are set. The area is clearly identified. In the example of FIG. 8, the background color is lightly displayed in the order of “large traffic jam”, “medium traffic jam”, and “small traffic jam”. Thereby, the user can sensuously recognize the traffic information of each area in the recommended route, and can appropriately select the facility to be routed based on this recognition.

In the present embodiment, the traffic jam information is generated based on information related to past traffic jams (for example, congestion information included in the road traffic information).
According to this, it is possible to appropriately set traffic information reflecting the traffic situation of the past road.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.
For example, in this embodiment, in the traffic jam information database 42, areas and traffic jam information are stored in association with each other. The traffic jam information database 42 is used to set traffic jam information for each area. When it becomes necessary to set traffic information in each area, the traffic information may be set as appropriate based on data related to traffic on the road stored in the hard disk 25.
Further, the search distance stored in association with the traffic jam information in the search distance database 43 is not limited to the distance given in FIG.

DESCRIPTION OF SYMBOLS 1 In-vehicle navigation apparatus 10 Control part 16 Display part

Claims (7)

In the in-vehicle navigation device that can search the route to the destination,
A route side facility search function for searching for facilities located within a predetermined search range from the route to the destination,
A control unit that, when executing the route side facility search function, adjusts the size of the search range based on traffic jam information related to a route to a destination, and executes a facility search. In-vehicle navigation device. The controller is
The facility search is performed after adjusting the size of the search range based on traffic jam information of an area including a route to a destination when the route side facility search function is executed. The in-vehicle navigation device according to 1. The controller is
When the route side facility search function is executed, the search range is narrowed as the road belonging to the area including the route to the destination is congested. On the other hand, the road is not congested. The in-vehicle navigation device according to claim 2, wherein the facility search is performed after the search range is widened. A display unit capable of displaying a map;
The controller is
When executing the route side search function, for each area divided on the map, the facility is searched after adjusting the size of the search range based on the traffic jam information related to the route to the destination,
The on-vehicle device according to claim 1, wherein the display unit displays each area on a map in a manner in which the degree of traffic jam for each area can be understood, and then displays a result of facility search in each area. Navigation device.   The in-vehicle navigation device according to any one of claims 1 to 4, wherein the traffic jam information related to the route to the destination is information generated based on information related to past traffic jams on the road. Control the in-vehicle navigation device that can search the route to the destination,
When executing the route side facility search function for searching for facilities located in a predetermined search range from the route to the destination, the size of the search range is adjusted based on the traffic jam information related to the route to the destination, and the facility The search method of the vehicle-mounted navigation apparatus characterized by performing this search. A computer-readable program that controls an in-vehicle navigation device that can search for a route to a destination,
The computer,
When executing the route side facility search function that searches for facilities located in a predetermined search range from the route to the destination, after adjusting the size of the search range based on the traffic jam information related to the route to the destination A program that functions as a control unit that executes a facility search.

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