JP5655123B2 - Navigation system and navigation method - Google Patents

Description

  The present invention relates to a navigation technique for guiding a user to a specified position.

A technical method has been proposed in which the navigation client reproduces the route searched by the navigation server by communication between the navigation server and the navigation client installed in the vehicle (
(See Patent Document 1). “Navigation” is an abbreviation for “navigation”.

  Specifically, link identification information for identifying a link constituting a part of the server route searched by the navigation server is transmitted to the navigation client. In response to this, the navigation client reads out the latitude and longitude coordinate string information representing the link associated with the link identification information from the storage device, and searches and outputs the client route based on the coordinate string information. Is done. At this time, by executing an interpolation process for connecting discontinuous portions that cannot be compensated only by the link identification information transmitted from the navigation server, a client route that completely or substantially matches the server route can be searched.

JP 2009-019924 A

  However, if the server map data used by the navigation server and the client map data used by the navigation client do not strictly match, there is a possibility that a client route that is significantly different from the server route is searched. The difference between the map data includes, for example, a difference in format such as a description method of link identification information in addition to a difference in the range of the covered links.

  Therefore, the present invention provides a system and the like that allows a navigation client to effectively use a route search result by a navigation server while allowing the difference in map data used by the navigation server and the navigation client to exist. With the goal.

The navigation system of the present invention is a navigation system configured by a navigation server and a navigation client, wherein each navigation point is described by coordinate values including latitude and longitude, and a link for calculating a route. A server storage device configured to store a server map described by a group of coordinate values, and designated point information including information of two designated points from the navigation client, and using the server map A first server calculation processing element configured to search for a server route configured by a plurality of links connecting the two specified points, and the server route searched by the first server calculation processing element A route in which the position and shape arrangement mode is expressed by coordinate values, and the movement cost for each link is included. A second server computation processing element configured to transmit information to the navigation client, wherein the navigation client is configured to display a client map including information on coordinate values of each point. An image output device, a first client calculation processing element configured to transmit the designated point information to the navigation server, the route information received from the navigation server, and included in the route information The image of the position and shape arrangement mode represented by the coordinate values and the position and shape arrangement mode that coincides in the client map is overlaid on the client map as a client route that reflects high and low movement cost information for each link. The second client arithmetic processing required to be output to the image output device Characterized in that it comprises and.

  In the navigation system of the present invention, the first server calculation processing element searches for a plurality of server routes, and the second server calculation processing element addresses the plurality of server routes to the navigation client as a plurality of route information, respectively. The second client computation processing element receives the plurality of route information from the navigation server, and the route designated by the user through the input device of the navigation client among the plurality of received route information. May be configured to be output to the image output device over the client map as a client route.

The navigation system according to the present invention is a navigation system including a navigation server and a navigation client, wherein each navigation point is described by coordinate values including latitude and longitude, and a link for calculating a route is provided. A server storage device configured to store a server map described by a group of coordinate values and a specific area including an entrance from an ordinary road to an expressway or an exit from an expressway to an ordinary road; A plurality of designated point information including two or more designated points is received from the client, and the two designated points are connected using the server map and the specific area information so as to increase the density of the specific area points. A first server arithmetic processing element configured to search for a server route configured by a link, and the first server arithmetic processing A second server arithmetic processing element configured to transmit the route information in which the position and shape of the server route searched by the element are expressed by coordinate values to the navigation client; The navigation client is configured to display a client map including coordinate value information of each point, and to transmit the designated point information to the navigation server. 1 client arithmetic processing element, and the route information received from the navigation server, and the position and shape arrangement modes that are represented by the coordinate values included in the route information and the position and shape arrangement modes that match in the client map The image is output to the image output device as a client route, overlaid on the client map. A, and a second client arithmetic processing element configured urchin.

The navigation method of the present invention is a server configured to store a server map in which each point is described by coordinate values including latitude and longitude, and a link for route calculation is described by a group of coordinate values. A method executed by a navigation server including a storage device and a navigation client including an image output device configured to display a client map including coordinate value information of each point, the navigation client including the A step of transmitting designated point information including information of two designated points to the navigation server; and the navigation server receives the designated point information from the navigation client and uses the server map to designate the two designated points. A step of searching for a server route constituted by a plurality of links connecting points; and Transmitting the route information to which the position and shape arrangement mode is expressed by coordinate values and including the level of movement cost for each link to the navigation client; and the navigation client includes the navigation server The position information of the position and shape represented by the coordinate value included in the route information and the image of the position and shape arrangement mode that match in the client map are received from each link. And a step of outputting the information to the image output device over the client map as a client route reflecting the above information .

  In the navigation method of the present invention, the navigation server searches for a plurality of server routes, and the navigation server transmits the plurality of server routes to the navigation client as a plurality of route information, respectively. The navigation server receives the plurality of route information from the navigation server, and the client specifies a route designated by the user through the input device of the navigation client among the plurality of received route information as the client route. And a step of outputting the image output device on the map.

Navigation method of the invention, each point is described by the coordinate values including the latitude and longitude, and the inlet or from the server map and general road link for route calculation are described by a group of coordinate values motorway A navigation server having a server storage device configured to store a specific area including an exit from an expressway to a general road, and configured to display a client map including information on coordinate values of each point A navigation method executed by a navigation client including an image output device, wherein the navigation client transmits designated point information including information on two designated points to the navigation server; , said receiving the specified point information from the navigation client, using and the server map and the specific area information, the land of a particular area A step of searching for a server route that the density of the is composed of a plurality of links connecting the two specified point to be higher, the navigation server, represented arrangement of the position and shape of the server route by the coordinate values Transmitting the route information being sent to the navigation client, and the navigation client receives the route information from the navigation server and is arranged in the position and shape expressed by the coordinate values included in the route information. And a step of superimposing an image of an arrangement mode of a position and shape in the client map on the client map as a client route and outputting the image on the client map.

  Note that “recognition” of information by the constituent element of the present invention means that the constituent element receives information, searches or reads from a database or memory, and performs specified arithmetic processing on basic information received or detected. To calculate, measure, estimate, set, determine, search, predict, etc., decode received packets to reveal information, and save calculated information in memory This means that any information processing for preparing the information for other information processing is performed.

  According to the navigation system, navigation method, and the like of the present invention, the arrangement mode f (p) such as the position, posture, and shape of the server route route 1 (dashed line) shown in the upper part of FIG. As shown in the lower part of the figure, the route information is extracted in a form expressed by coordinate values for specifying each point (see FIG. 2 / STEP 120).

  Then, the arrangement form f (p) of the server route route 1 shown in the upper part of FIG. 6B is shown in the client map map 2 in which each point is described by coordinate values as shown in the lower part of the figure. As a result of reproduction, a client route route 2 (two-dot chain line) is output. That is, the image data of the server route route1 and the image data of the client map map2 are superimposed so that the position, orientation, and shape are matched by the coordinate value that is a common description part of both maps map1 and map2, and the output device 202.

  Thus, the presence of a common description of coordinate values allows the navigation client 100 to display the route search result by the navigation server 100 while allowing the difference in map data used by the navigation server 100 and the navigation client 200, respectively. 200 can be used effectively. That is, even if the server map and the client map are different in the format such as the description method of the link identification information of the common link, the route search result by the navigation server 100 can be effectively used by the navigation client 200.

Therefore, the user can be smoothly guided to the destination point p ₂ according to the client route as a result of reproducing the server route in the navigation client 200.

  Since the route information includes the level of the link travel cost, the navigation client can recognize the information about the travel cost even if the navigation client has no information about the travel cost. Can be grasped. As a result, the route search result by the navigation server can be effectively used by the navigation client.

In addition, since the server route is searched so that the link density of a specific area including the entrance from the general road to the expressway or the exit from the expressway to the general road is increased, the navigation is performed while suppressing the amount of data to be transmitted and received. The server route is reproduced with high reproducibility on the client. As a result, the route search result by the navigation server can be effectively used by the navigation client.

The block diagram of the navigation system as one Embodiment of this invention. Explanatory drawing of the procedure of the navigation method as one Embodiment of this invention. Explanatory drawing regarding the setting method of the 1st designated point of a server route. Explanatory drawing regarding the setting method of the 2nd designated point of a server route. Explanatory drawing regarding the search method of the server route in the vicinity of a designated point. Explanatory drawing regarding the reproduction method of the client route based on a server route.

(Configuration of navigation system)
The navigation system shown in FIG. 1 includes a navigation server 100 and a navigation client 200. Among the plurality of navigation clients 200, at least some of the navigation clients 200 may function as the navigation server 100 temporarily or regularly.

  The navigation server 100 includes a server storage device 104, a first server arithmetic processing element 110, and a second server arithmetic processing element 120. The navigation server 100 has a communication function with the navigation client 200 via a network, and is configured by one or a plurality of server computers. As the communication network, the Internet, a telephone line network, a communication network using satellite broadcasting, or the like can be adopted.

  The server storage device 104 is configured to store a server map in which each point is described by latitude and longitude. According to the server map, a link connecting two separated points (intersection etc.) is described by a coordinate value group or a coordinate string representing a plurality of points on the link. At least some of the links may be described in association with link identification information for identifying the link or the type of road constituted by the link. In addition, the location ranges such as parks, rivers, and facility sites are described by coordinate strings representing a plurality of points on the contour lines or closed curves of the ranges. Each range may be described in association with the type of object located in the range.

  The first server computation processing element 110 is configured to receive designated spot information from the navigation client 200 and recognize (determine) each of the two designated spots based on the designated spot information. The first server computation processing element 110 is configured to search for one or a plurality of server routes configured by a plurality of links connecting two designated points using a server map.

  The second server arithmetic processing element 120 creates route information in which the arrangement form of the server route searched by the first server arithmetic processing element 110 is expressed by coordinate values, and then sends the route information to the navigation client 200. Are configured to transmit.

  Each of the first server arithmetic processing element 110 and the second server arithmetic processing element 120 is configured by a programmable computer. The fact that the component of the present invention executes the assigned information calculation process means that the component is programmed to read the program from the memory and execute the assigned information calculation process according to the program. The program is downloaded to the navigation server 100 via a network or installed via a storage medium. Each of the first server arithmetic processing element 110 and the second server arithmetic processing element 120 may be partially or entirely configured by physically independent and separate hardware.

  The navigation client 200 includes an input device 201, an output device 202, a client storage device 204, a first client arithmetic processing element 210, and a second client arithmetic processing element 220. The navigation client 200 may be configured by a portable device, or may be configured as a device that is regularly or temporarily mounted on a vehicle.

  The input device 201 is configured by a push button type or touch panel type interface, and enables an information input operation such as designation input of a destination point by a user. You may be comprised by the audio | voice recognition apparatus which analyzes the acoustic signal collected by the microphone and the said microphone, and recognizes (determines) the user's utterance content or the information intended for input.

  The output device 202 is configured by an image output device including a liquid crystal panel on which a client map or the like is displayed. When the input device 201 is configured by a touch panel interface, a touch button is displayed on the image output device. The output device 202 may be configured by an audio output device that outputs an audio signal related to the image information displayed on the image output device in addition to the image output device.

  The client storage device 204 is configured to store a client map in which each point is described by latitude and longitude. According to the client map, a link connecting two separated points is described by a coordinate value group or a coordinate string representing a plurality of points on the link. At least some of the links may be described in association with link identification information for identifying the link or the type of road constituted by the link. In addition, the location ranges such as parks, rivers, and facility sites are described by coordinate strings representing a plurality of points on the contour lines or closed curves of the ranges. Each range may be described in association with the type of object located in the range.

  The client map may be the same map as the server map, or may be a map that differs in at least a part of the format from the server map.

  The first client calculation processing element 210 is configured to create designated point information and transmit the designated point information to the navigation server 100. The “designated point information” is information that serves as a basis for recognizing (deciding) the coordinate values of the designated points that are the two end points of the server route. The first client calculation processing element 210 is configured to measure the current position of the navigation client 200 based on a GPS signal or the like received by a GPS receiver (not shown) mounted on the navigation client 200. The first client arithmetic processing element 210 is configured to recognize (determine) a destination point or the like input by the user through the input device 201.

  The second client calculation processing element 220 is configured to receive route information from the navigation server 100 and designate a point in the client map based on the coordinate value of the designated point included in the route information. The second client arithmetic processing element 220 overlaps the client map with a route having a certain arrangement relationship with the point and having the same server route shape included in the route information as the client route, and outputs to the output device 202. It is comprised so that it may output.

  Each of the first client arithmetic processing element 210 and the second client arithmetic processing element 220 is configured by a programmable computer. The program is downloaded to the navigation client 200 via a network or installed via a storage medium. Each of the first client arithmetic processing element 210 and the second client arithmetic processing element 220 may be partially or entirely configured by physically independent and separate hardware.

(Navigation method)
An embodiment of a navigation method executed by the navigation system having the above configuration will be described.

In the navigation client 200, the first client arithmetic processing element 210, destination point (more precisely, the coordinate values) of the user p ₂ is recognized (determined) (Fig. 2 / STEP212). For example, the client maps displayed on the output device 202, a point specified by the user is recognized as a destination point p ₂ (decision) through the input device 201.

A mark representing a plurality of destination point candidates is displayed on the client map, and a destination point candidate corresponding to one mark selected by the user through the input device 201 is recognized (determined) as the destination point p _2. Also good. A mark representing the position of a destination point candidate is a mark representing the position of a POI that is classified into a preference category registered in advance in the navigation client 200 by the user through the input device 201 from among a large number of POIs (Point of Interest). May be displayed on the client map.

In addition, the facility name, etc., address, basic information such as a telephone number or e-mail address is inputted or specified by the user through the input device 201, recognition sites associated with the basic information in the client maps the destination point p ₂ (Determined).

The first client computation processing element 210 recognizes (determines) the user's departure point (exactly its coordinate value) p ₁ (FIG. 2 / STEP 211). For example, the current location of the navigation client 200 at the time when the destination point p ₂ is recognized (determined) is recognized (determined) as the departure point p ₁ . In addition, similarly to the destination point p ₂ , a point designated by the user through the input device 201 may be recognized as the departure point p ₁ .

Then, the first client calculation processing element 210 creates “designated point information” including the coordinate values of the departure point p ₁ and the destination point p ₂ of the navigation client 200 (FIG. 2 / STEP 214). The designated point information is transmitted to the navigation server 100 (see arrow 01 in FIG. 2). Accompanying the designated point information, client identification information for identifying the navigation client 200 is also transmitted to the navigation server 100.

Subsequently, in the navigation server 100, the first server computation processing element 110 receives the designated spot information from the navigation client 200, and recognizes (determines) each of the two designated spots based on the designated spot information (FIG. 2 / STEP 112). For example, each of the starting point p ₁ and the destination point p ₂ included in the designated point information is a first designated point (exactly its coordinate value) q ₁ and a second designated point (exactly its coordinate value) q _2. Are recognized (determined).

Points around the departure point p ₁ may be recognized (determined) as the first designated point q ₁ . For example, a point on the link at the shortest distance is recognized (determined) as the first specified point q ₁ from the starting point p _1.

In addition, the first server calculation processing element 110 changes the neighboring route constituted by one or more links connecting the departure point p ₁ and the point out of the points around the departure point (reference point) p _1. A point along which the moving cost of the user along is relatively low may be recognized (determined) preferentially as the first designated point q ₁ .

  When evaluating the movement cost, a server map in which the movement cost of the user at each link is described by the server map is used. The moving cost is a moving distance, a required moving time, a user's physical load, or a function value having at least one of these as variables. When the user moves by a vehicle, the distance of the vehicle, the time required for movement, the user's physical load (vehicle driving load), the predicted fuel consumption or the required fee, or the value of a function having at least one of these as variables Corresponds to the moving cost.

  The travel time for each link can be recognized (determined) from road traffic information obtained from an external information source. In addition to the measuring device installed to measure the traffic volume of the user or vehicle of each link and the navigation client 200 as a probe device that measures the current position in time series, from the measuring device or the probe device A road traffic information center or the like configured to analyze the collected information and predict the required travel time for each link after collecting the measurement results corresponds to the external information source. The navigation server 100 may constitute the road traffic information center.

As shown in FIG. 3A, the linear distance from the starting point p ₁ is short, but the first factor Obs1 (river, forest, park, building, or its site, etc.) that the user cannot pass is used as a reference. If the point on the opposite side of the starting point p ₁ is recognized (determined) as the first designated point q ₁ (1), the moving cost of the user along the neighboring route (broken line) increases. Is highly appreciated.

Meanwhile, also FIG. 3 though the linear distance is longer from the starting point p1 as shown (a), the point viewed from the first factor Obs1 on the same side as the departure point p ₁ is first specified point q ₁ When recognized (determined) as (2), the travel cost is evaluated low because the travel distance of the user along the neighboring route (broken line) is shortened. Accordingly, the latter of the two points q ₁ (1) and q ₁ (2) is recognized (determined) as the first designated point q ₁ .

  Further, as shown in FIG. 3B, the second factor Obs2 (the user's travel distance along the neighboring route (broken line) is short, but the neighboring route is accessible to the user but difficult to pass. Travel costs are highly valued when passing through roads or areas where there is traffic congestion or congestion, roads with many slopes, roads passing through railroad crossings, and the like. The inclination of each link can be determined by using a server map in which each point is described by coordinate values including altitude in addition to latitude and longitude.

On the other hand, as shown in FIG. 3B, the movement distance of the user along the neighboring route (broken line) is long, but when the neighboring route does not pass the second factor Obs2, the movement cost is Rated low. Accordingly, the latter of the two points q ₁ (1) and q ₁ (2) is recognized (determined) as the first designated point q ₁ .

Further, although FIG 4 linear distance to the destination point p ₂ as shown in (a) is short, the point that the destination point p ₂ a first factor Obs1 based on the opposite side of the second specified point q _{2 When} recognized (determined) as (1), the moving cost is highly evaluated as the moving distance of the user along the neighboring route (broken line) becomes longer. Meanwhile, similarly although FIG linear distance to the destination point p ₂ as shown in (a) is a long, point first factor Obs1 viewed from Te on the same side as the destination point p ₂ is the second specified point q _{2 When} recognized (determined) as (2), the moving cost is evaluated low because the moving distance of the user along the neighboring route (broken line) is shortened. Accordingly, the latter of the two points q ₂ (1) and q ₂ (2) is recognized (determined) as the second designated point q ₂ .

Further, as shown in FIG. 4B, although the moving distance of the user along the neighboring route (broken line) is short, the moving cost is highly evaluated when the neighboring route passes the second factor Obs2. The On the other hand, as shown in FIG. 4B, the movement cost of the user along the neighboring route (broken line) is long, but if the neighboring route does not pass through the second factor Obs2, the movement cost is Rated low. Accordingly, the latter of the two points q ₂ (1) and q ₂ (2) is recognized (determined) as the second designated point q ₂ .

Subsequently, the first server calculation processing element 110 searches for one or a plurality of server routes configured by a plurality of links connecting the first designated point q ₁ and the second designated point q ₂ using the server map. (FIG. 2 / STEP 114).

For example, the server route is searched according to a policy that the moving cost to the first designated point q ₁ and the second designated point q ₂ is minimized. The type of travel cost designated by the user through the input device 201 is transmitted from the navigation client 200 to the navigation server 100 together with designated point information (see arrow 01 in FIG. 2), so that the travel cost of the designated type is minimized. A route may be searched.

Specifically, as shown in FIG. 5 (a), if the first doorway specified range A ₁ including the first specified point q ₁ is in contact with both-way street (dashed line), the both server route that advance is to advance the user in a relatively easy way from the first specified range a ₁ is searched in the way street. For example, if both traffic roads are roads left side of the road, the route R (1) rather than as to advance while turning right from the first specified range A _1, route as to advance while left from the first specified range A1 R (2) is preferentially searched as a server route. On the other hand, when both the two-way roads are right-hand roads, the other route R (1) is preferentially searched as a server route.

In addition, as shown in FIG. 5B, when the entrance / exit of the second designated range A ₂ including the second designated point q ₂ is in contact with a both-passage road (broken line), A server route that causes the user to travel in a direction in which entry into the second designated range A ₂ is relatively easy is searched. For example, as both-way street be a road of left-hand traffic, the root R (1) rather than as entering while turn right to the second specified range A _2, enters while left in the second specified range A ₂ Route R (2) is preferentially searched as a server route. On the other hand, when both the two-way roads are right-hand roads, the other route R (1) is preferentially searched as a server route.

  Next, “route information” in which the arrangement form of the server route is expressed by coordinate values is created by the second server computation processing element 120 (FIG. 2 / STEP 120), and the route information is designated as specified point information. Is transmitted to the navigation client 200 identified by the client identification information attached to (see FIG. 2 / arrow 01) (FIG. 2 / arrow 02).

The route information includes coordinate values of a plurality of points on the server route including at least the first designated point q ₁ to the second designated point q ₂ . The density of the plurality of points can be appropriately adjusted in consideration of the communication cost of route information. In addition, the density of points is slightly different, such as the point density in areas with high importance, such as entrances from general roads to expressways or exits from highways to general roads, is higher than other locations. Also good.

  In addition, in the route information, in addition to at least one point on the server route, one or more functions y = f (x) (x: The arrangement mode may be expressed by latitude, y: longitude). By expressing the arrangement mode of at least a part of the server route including a plurality of points by the function, the communication cost of the route information and the calculation processing load thereof are reduced.

  The route information may include the level of movement cost for each link and designation of the display form (color or brightness) of each link according to the level of the movement cost.

  Then, the route information is received by the second client arithmetic processing element 220 in the navigation client 200. Then, a route having an arrangement mode represented by the coordinate value included in the route information and an arrangement mode matching the client map is generated as a client route, and is output to the output device 202 over the client map (FIG. 2 / (STEP 220).

  If the route information includes the coordinate values of a plurality of points on the server route, a plurality of points having the coordinate values are identified on the client map, and then a line segment connecting the plurality of points Drawing data is generated as a client route. Drawing data of the client route so that each link is displayed on the output device 202 in accordance with a display form according to at least one of the road type difference and the movement cost specified by the route information. May be generated.

  In addition, in the route information, at least one point on the server route and a point having the coordinate value on the client map are specified, and one or more functions y = f (x) based on the point Thus, drawing data representing the posture and shape is generated as a client route.

  A plurality of types of client maps may be stored in the client storage device 204, and the types of client maps specified by the user through the input device 201 may be displayed on the output device 202.

(Other embodiments of the present invention)
According to the embodiment, the server map corresponds to a “designated map” in which the movement cost of the user of the navigation client 200 at each link is described, and the navigation server 100 is a “designated device” that uses the designated map. Corresponding and the first server arithmetic processing element 110 corresponds to the “first designated arithmetic processing element” using the designated map.

  Instead, for at least some of the navigation clients 200, the client map corresponds to the “designated map”, the navigation client 200 corresponds to the “designated device”, and the first client arithmetic processing element 210 is the “first map”. It may correspond to “designated arithmetic processing element”.

In this case, the first client calculation processing element 210 recognizes (determines) the starting point p ₁ or a point around it as the first designated point q ₁ (see FIGS. 3A and 3B) and the purpose. The point p ₂ or a point around it is recognized (determined) as the second designated point q ₂ (see FIGS. 4A and 4B).

Then, the first client calculation processing element 210 generates designated point information in which each of the first designated point q ₁ and the second designated point q ₂ is expressed by coordinate values (see FIG. 2 / STEP 214). After that, the first designated point q ₁ and the second designated point q ₂ are recognized (determined) directly from the designated point information by the first server calculation processing element 110.

  DESCRIPTION OF SYMBOLS 100 ... Navi server, 104 ... Server memory | storage device, 110 ... 1st server arithmetic processing element, 120 ... 2nd server arithmetic processing element, 200 ... Navi client, 204 ... Client storage device, 210 ... 1st client arithmetic processing element, 220 ... second client calculation processing element.

Claims (6)

A navigation system composed of a navigation server and a navigation client,
The navigation server
A server storage device configured to store a server map in which each point is described by coordinate values including latitude and longitude, and a link for route calculation is described by a group of coordinate values;
It is configured to receive designated point information including information of two designated points from the navigation client, and to search for a server route constituted by a plurality of links connecting the two designated points using the server map. A first server computation processing element,
The route information including the position and shape arrangement of the server route searched by the first server processing element is expressed by coordinate values, and the moving cost of each link is included in the navigation client. A second server computing element configured to transmit to,
The navigation client
An image output device configured to display a client map including information of coordinate values of each point;
A first client computing element configured to transmit the designated point information to the navigation server;
Receiving the route information from the navigation server , moving the image of the position and shape arrangement mode represented by the coordinate value included in the route information in the client map for each link A navigation system comprising: a second client arithmetic processing element configured to output the image to the image output device over the client map as a client route reflecting high and low cost information . The navigation system according to claim 1, wherein
The first server computing element searches for a plurality of server routes;
The second server computation processing element transmits the plurality of server routes to the navigation client as route information, respectively.
The second client computation processing element receives the plurality of route information from the navigation server, and uses a route designated by the user through the input device of the navigation client among the plurality of received route information as a client route. A navigation system configured to be output to the image output device over the client map. A navigation system composed of a navigation server and a navigation client,
The navigation server
A server map in which each point is described by coordinate values including latitude and longitude, and a link for route calculation is described by a group of coordinate values, and an entrance from an ordinary road to an expressway or an expressway to an ordinary road A server storage device configured to store a specific area including an exit ; and
Receiving said specified point information includes two or more specified point from the navigation client, above using the server maps to the specific area information, the two specified points as the density of a point of a specific area higher A first server arithmetic processing element configured to search for a server route configured by a plurality of links to be connected;
A second server computation configured to transmit to the navigation client route information in which an arrangement mode of the position and shape of the server route searched by the first server computation processing element is expressed by coordinate values. With processing elements,
The navigation client
An image output device configured to display a client map including information of coordinate values of each point;
A first client computing element configured to transmit the designated point information to the navigation server;
The route information is received from the navigation server, and an image of a position and shape arrangement mode that is coincident in the client map with a position and shape arrangement mode represented by the coordinate values included in the route information is used as the client route. A navigation system, comprising: a second client arithmetic processing element configured to be output to the image output device over a client map. A navigation server comprising a server storage device configured to store a server map in which each point is described by coordinate values including latitude and longitude, and a link for route calculation is described by a group of coordinate values; ,
A method performed by a navigation client including an image output device configured to display a client map including information on coordinate values of each point,
The navigation client transmitting designated point information including information of two designated points to the navigation server;
The navigation server receives the designated point information from the navigation client, and uses the server map to search for a server route constituted by a plurality of links connecting the two designated points;
The navigation server transmits route information to the navigation client, wherein route information including the position and shape of the server route is expressed by coordinate values and includes a moving cost for each link. ,
The navigation client receives the route information from the navigation server, and displays an image of a position and shape arrangement mode that matches the position and shape arrangement mode represented by the coordinate values included in the route information in the client map. And a step of outputting the information to the image output device over the client map as a client route reflecting information on the moving cost of each link . The navigation method according to claim 4 , wherein
The navigation server searches for a plurality of server routes;
The navigation server sends the plurality of server routes to the navigation client as route information, respectively;
The navigation server receives the plurality of route information from the navigation server, and uses the route specified by the user through the input device of the navigation client among the plurality of received route information as a client route, the client map. And a step of outputting the image output device to the image output device. A server map in which each point is described by coordinate values including latitude and longitude, and a link for route calculation is described by a group of coordinate values, and an entrance from an ordinary road to an expressway or an expressway to an ordinary road A navigation server comprising a server storage device configured to store a specific area including an exit ; and
A navigation method performed by a navigation client including an image output device configured to display a client map including information on coordinate values of each point,
The navigation client transmitting designated point information including information of two designated points to the navigation server;
The navigation server receives the designated point information from the navigation client, and uses the server map and the specific area information to connect the two designated points so as to increase the density of the specific area points. Searching for a server route configured by a link of
The navigation server sends the route information in which the position and shape of the server route are expressed by coordinate values to the navigation client;
The navigation client receives the route information from the navigation server, and displays an image of a position and shape arrangement mode that matches the position and shape arrangement mode represented by the coordinate values included in the route information in the client map. And a step of causing the image output apparatus to output the client route so as to overlap the client map.