JP2020115135A - Image transmission system, terminal, image transmission method, and image transmission program - Google Patents

Abstract

To make it possible to transmit, before reaching a required position, an image appropriate at the time of reaching the required position.SOLUTION: An image transmission device 101 includes: an acquisition part 102 for acquiring an image and location information on where the image was photographed; a recording part 103 for recording the image and the location information in association with each other; and a transmission part 104 for transmitting the image, which is associated with the location information corresponding to a predetermined position and which is adapted to a situation of the predetermined position at the time when a terminal 111 reaches the predetermined position, to the terminal 111 when acquiring, from the terminal 111, an acquisition request of the image photographed at the predetermined position.SELECTED DRAWING: Figure 1

Description

The present invention relates to an image transmission system, a terminal, an image transmission method, and an image transmission program for transmitting a captured image to a terminal. However, the use of the present invention is not limited to the image transmission system, the terminal, the image transmission method, and the image transmission program.

Conventionally, by uploading image data taken by a camera mounted on a vehicle to a server, the server collects images, selects the latest image for each point such as an intersection from the images collected by the server, and travels. A system for delivering an image to a terminal of an inside vehicle has been proposed (for example, refer to Patent Document 1 below).

International Publication No. 2008/047449

In the above conventional technique, the latest image can be acquired by the terminal, but at the time when the user actually arrives at that point, the time is different from the acquired image, traffic congestion situation, driving lane (shooting lane) The problem is that it is difficult for the user to grasp the situation of the spot even when looking at the image.

In order to solve the above-mentioned problems and achieve the object, an image transmission system according to claim 1 of the present invention includes an image and a recording unit that records the position information of the image in association with each other. If an acquisition request for an image captured at a predetermined point is acquired, the situation of the point at the time when the terminal is associated with the position information corresponding to the predetermined point and the terminal reaches the predetermined point is obtained. Transmitting means for transmitting the adapted image to the terminal.

Further, the terminal according to the invention of claim 5 transmits a camera for capturing an image, the image, position information and date and time information of capturing the image, and the terminal corresponding to the time to reach a predetermined point. A transmission unit that transmits an acquisition request for the image associated with the date and time information, a reception unit that receives the image corresponding to the acquisition request, and a display unit that displays the received image. And

The image transmitting method implemented by the image transmitting apparatus according to the invention of claim 6 includes: a recording step of recording the image and position information of the image in association with each other; and an image captured from a terminal at a predetermined point. When the acquisition request is acquired, an image that is associated with the position information corresponding to the predetermined point and that matches the situation of the point at the time when the terminal reaches the predetermined point is transmitted to the terminal. And a transmitting step to perform.

The image transmitting method according to the invention of claim 7 is the image transmitting method carried out by a terminal, comprising transmitting an image capturing step of capturing an image, the image, position information and date and time information of capturing the image, A transmitting step of transmitting an acquisition request of the image associated with the date and time information corresponding to the time when the vehicle reaches a predetermined point, a receiving step of receiving the image corresponding to the acquisition request, and the received image And a display step of displaying.

An image transmitting program according to the invention of claim 8 causes a computer to execute the image transmitting method according to claim 6 or 7.

FIG. 1 is a block diagram showing an example of the functional configuration of the image transmission system according to the embodiment. FIG. 2 is a flowchart showing an example of the processing procedure of the image transmission system according to the embodiment. FIG. 3 is a block diagram showing an example of the hardware configuration of the navigation device. FIG. 4 is a chart showing an example of a database recorded in the image transmitting apparatus. FIG. 5 is a table for explaining a method of selecting a combination of database parameters when specifying an image. FIG. 6 is a flowchart illustrating processing contents from image capturing to database storage according to the first embodiment. FIG. 7 is a flowchart illustrating the processing content of image transmission corresponding to the request according to the first embodiment. FIG. 8 is a diagram showing an example of an image displayed by the terminal. (Part 1) FIG. 9 is a diagram showing an example of an image displayed by the terminal. (Part 2) FIG. 10 is a diagram showing an example of an image displayed by the terminal. (Part 3) FIG. 11 is a flowchart illustrating processing contents from image capturing to database storage according to the second embodiment. FIG. 12 is a flowchart illustrating processing details of image transmission corresponding to the request according to the second embodiment.

(Embodiment)
Hereinafter, preferred embodiments of an image transmission system, a terminal, an image transmission method, and an image transmission program according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing an example of the functional configuration of the image transmission system according to the embodiment. The image transmission system 100 according to the embodiment includes an image transmission device 101 and a terminal 111.

The image transmission device 101 includes an acquisition unit 102, a recording unit 103, and a transmission unit 104. In an embodiment, a single server has each of these functions. Further, it may be configured to use a plurality of servers distributed according to functions, and further, a single client (terminal 111) may have the function of the image transmitting apparatus 101 without using the server.

The acquisition unit 102 is communicatively connected to the terminal 111 via a network 121 such as the Internet, and acquires an image and position information and date/time information of the image from the terminal 111. The recording unit 103 records an image, position information, and date/time information in association with each other in a memory (not shown) or the like. As a result, a database including a plurality of images, positions, and dates is created in the recording unit 103.

When the transmission unit 104 acquires an acquisition request for an image captured at a predetermined point from the terminal 111, the transmission unit 104 is associated with the position information corresponding to the predetermined point, and at the time when the terminal 111 reaches the predetermined point. The image associated with the corresponding date/time information is read from the recording unit 103 and transmitted to the terminal 111.

The terminal 111 includes a camera 112, a communication unit 113, and a display unit 114. The terminal 111 is mounted on, for example, a moving body (vehicle). The camera 112 captures an image including a road when the vehicle is moving, and transmits the image to the image transmitting apparatus 101 via the communication unit 113. At this time, the terminal 111 transmits the image capturing position (for example, latitude and longitude measured by GPS) and the date and time information of the image capturing together with the image to the image transmitting apparatus 101.

Further, the terminal 111 requests the image transmitting apparatus 101 to acquire an image captured at a desired predetermined point. The terminal 111 receives the image transmitted from the image transmitting apparatus 101 in response to the acquisition request via the communication unit 113. The received image of the desired position is displayed and output on the display unit 114.

Here, it is assumed that the terminal 111 makes an acquisition request for an image of a predetermined point on the planned route along which the vehicle travels due to route search or the like. In this case, the terminal 111 or the image transmission device 101 calculates the time when the vehicle reaches a predetermined point. Then, the transmission unit 104 transmits the image of this point at the time of reaching the predetermined point to the terminal 111. As a result, the terminal 111 can acquire an image when the vehicle reaches a predetermined point before reaching the predetermined point on the planned route.

The image transmission device 101 transmits to the terminal 111 an image of a predetermined point at the time when the vehicle arrives at the predetermined point when the terminal 111 makes a request. The image transmitting apparatus 101 is not limited to transmitting an image in response to such a request from the terminal 111 (user side). When an event such as a sudden weather change or a sudden accident occurs, the image transmitting apparatus 101 may dynamically deliver a new image corresponding to the occurrence of the event to the terminal 111.

Further, either the terminal 111 or the image transmission device 101 may have a function of performing image analysis on a captured image. By analyzing the captured image, information on the traffic lane and the traffic lane at a predetermined point is calculated. When the terminal 111 analyzes an image, it transmits analysis information (congestion status, traveling lane) together with the image to the image transmission device 101, and the image transmission device 101 associates the image with the position, the date and time, and the analysis information, and the recording unit. Record in 103.

When the image transmitting apparatus 101 analyzes the image, the image received from the terminal 111, the position, and the date and time information are recorded in the recording unit 103 in association with the analysis information obtained by the image analysis.

In addition, the terminal 111 or the image transmission device 101 may acquire weather information corresponding to the position of the image and record it in association with the image. This makes it possible to improve image analysis accuracy by using visibility information such as rainfall, snowfall, and thick fog, which is indicated by climate information, and road surface conditions such as flooding, snowfall, and freezing.

As a result, the weather information is stored in the recording unit 103 together with the image and the analysis information after the image analysis. Then, the image transmitting apparatus 101 can transmit to the terminal the traffic jam condition according to the climate when the terminal 111 reaches the requested position and the information about the traveling lane together with the image.

FIG. 2 is a flowchart showing an example of the processing procedure of the image transmission system according to the embodiment. The processing of each of the image transmission device 101 and the terminal 111 is described.

In the processing on the terminal 111 side, the vehicle performs positioning by GPS or the like while moving, and the camera 112 captures an image including a road at a predetermined position (step S201). The photographing position of the photographed image may be periodically set at regular intervals, may be set every time a set position such as an intersection is reached, or may be set at an arbitrary position by a user operation.

Next, the terminal 111 transmits the captured image to the image transmitting apparatus 101 via the communication unit 113 (step S202). At this time, the shooting position and time obtained by the positioning are added and transmitted to the image transmitting apparatus 101.

On the image transmission device 101 side, the acquisition unit 102 receives the image transmitted from the terminal 111 (step S211). The recording unit 103 records the shooting position and the time of this image as an association database (step S212).

After that, when the terminal 111 requests the image transmitting apparatus 101 to transmit the image at the predetermined position at a predetermined time (step S203), the image transmitting apparatus 101 transmits the image at the position and time corresponding to the request to the terminal 111. Yes (step S213).

At this time, the terminal 111 or the image transmitting apparatus 101 may calculate the position according to the request and transmit the image according to the position to the terminal 111. For example, when the vehicle of the terminal 111 is moving, the terminal 111 or the image transmitting apparatus 101 calculates the time when the terminal (vehicle) 111 moves from the current position to the predetermined position, and the predetermined time corresponding to this time is calculated. The image of the position is read from the recording unit 103 and transmitted to the terminal 111.

The terminal 111 displays and outputs the received image (step S204). This allows the user of the terminal 111 to acquire an image when reaching a predetermined position on the planned route. The user will be able to predict traffic conditions based on this image.

In addition, if the image captured by the terminal 111 or the image transmission device 101 is image-analyzed and the analysis information (for example, traffic jam condition, driving lane) is recorded together with the image, in addition to the image, the requested terminal 111 is added to the image. , Analysis information can be added and transmitted.

Furthermore, if the terminal 111 or the image transmission device 101 is configured to record the weather information at the time of image acquisition together with the image, the image corresponding to the climate at the time when the terminal 111 reaches a predetermined point is displayed. It will be possible to send to 111. As a result, it becomes possible to provide an image and analysis information suitable for the situation when the terminal 111 actually reaches a predetermined point.

According to the above-described embodiment, the image transmitting apparatus can store the images acquired from the terminal in the database for each shooting position and time, and can send the image corresponding to the position and time requested by the terminal to the requesting terminal. .. As a result, the terminal can acquire images at unreachable positions and times in advance. In addition, it becomes possible to acquire the road condition (congestion condition) and weather information at the unreachable position, and the image and road condition suitable for the condition when the terminal actually reaches a predetermined point can be obtained in advance. It can be provided to the terminal.

Next, a first embodiment of the present invention will be described. In the first embodiment, the navigation device 300 is mounted on the user's vehicle and is communicatively connected to the server. Then, an example in which the server executes the functions of the image transmitting apparatus 101 will be described.

(Hardware Configuration of Navigation Device 300)
FIG. 3 is a block diagram showing an example of the hardware configuration of the navigation device. In FIG. 3, the navigation device 300 includes a CPU 301, a ROM 302, a RAM 303, a magnetic disk drive 304, a magnetic disk 305, an optical disk drive 306, an optical disk 307, an audio I/F (interface) 308, a microphone 309, a speaker 310, an input device 311, and The image I/F 312, the display 313, the communication I/F 314, the GPS unit 315, various sensors 316, and the camera 317 (corresponding to the camera 112 in FIG. 1) are provided. The components 301 to 317 are connected to each other by a bus 320.

The CPU 301 controls the entire navigation device 300. The ROM 302 records a boot program and an image transmission program. The RAM 303 is used as a work area for the CPU 301. That is, the CPU 301 controls the entire navigation device 300 by executing various programs recorded in the ROM 302 while using the RAM 303 as a work area.

The magnetic disk drive 304 controls the reading/writing of the data with respect to the magnetic disk 305 according to control of CPU301. The magnetic disk 305 records the data written under the control of the magnetic disk drive 304. As the magnetic disk 305, for example, HD (hard disk) or FD (flexible disk) can be used.

Further, the optical disc drive 306 controls reading/writing of data with respect to the optical disc 307 under the control of the CPU 301. The optical disc 307 is a removable recording medium from which data is read out under the control of the optical disc drive 306. The optical disc 307 can also use a writable recording medium. As the removable recording medium, an optical disk 307, an MO, a memory card, or the like can be used.

Examples of information recorded on the magnetic disk 305 and the optical disk 307 include map data, vehicle information, images, travel history, and the like. Map data is used when a route is searched for in a navigation system, and is background data that represents features such as buildings, rivers, the ground surface, energy supply facilities, and road shape data that represents the shape of roads with links and nodes. It is vector data including such as.

The audio I/F 308 is connected to the microphone 309 for audio input and the speaker 310 for audio output. The voice received by the microphone 309 is A/D converted in the voice I/F 308. The microphone 309 is installed in, for example, the dashboard section of the vehicle, and the number thereof may be one or more. From the speaker 310, a sound obtained by D/A converting a predetermined sound signal in the sound I/F 308 is output.

Examples of the input device 311 include a remote controller having a plurality of keys for inputting characters, numerical values, various instructions, a keyboard, a touch panel, and the like. The input device 311 may be realized by any one form of a remote controller, a keyboard, and a touch panel, but may be realized by a plurality of forms.

The video I/F 312 is connected to the display 313. Specifically, the video I/F 312 is output from, for example, a graphic controller that controls the entire display 313, a buffer memory such as a VRAM (Video RAM) that temporarily stores image information that can be immediately displayed, and a graphic controller. It is configured by a control IC or the like that controls the display 313 based on the image data to be displayed.

The display 313 displays various data such as icons, cursors, menus, windows, and characters and images. As the display 313, for example, a TFT liquid crystal display, an organic EL display or the like can be used.

The camera 317 captures an image of, for example, a road outside the vehicle. The image may be either a still image or a moving image. For example, the camera 317 captures the outside of the vehicle, the captured image is analyzed by the CPU 301, and the recording medium such as the magnetic disk 305 or the optical disc 307 is transferred via the video I/F 312. Or output to.

The communication I/F 314 is wirelessly connected to the network and functions as an interface between the navigation device 300 and the CPU 301. Communication networks that function as networks include in-vehicle communication networks such as CAN and LIN (Local Interconnect Network), public line networks, mobile telephone networks, DSRC (Dedicated Short Range Communication), LAN, WAN, and the like. The communication I/F 314 is, for example, a public line connection module, an ETC (nonstop automatic fee payment system) unit, an FM tuner, a VICS (Vehicle Information and Communication System)/beacon receiver, or the like.

The GPS unit 315 receives radio waves from GPS satellites and outputs information indicating the current position of the vehicle. The output information of the GPS unit 315 is used when the CPU 301 calculates the current position of the vehicle together with the output values of various sensors 316 described later. The information indicating the current position is information specifying one point on the map data, such as latitude/longitude and altitude.

The various sensors 316 output information such as a vehicle speed sensor, an acceleration sensor, an angular velocity sensor, and an inclination sensor for determining the position and behavior of the vehicle. The output values of the various sensors 316 are used by the CPU 301 to calculate the current position of the vehicle and the amount of change in speed and direction.

(Server configuration example)
The server used as the image transmission device 101 also has the same configuration as in FIG. It should be noted that this server does not require the GPS unit 315, various sensors 316, camera 317, etc. shown in FIG.

The image transmission device 101 shown in FIG. 1 obtains an image by executing a predetermined program by the CPU 301 using the programs and data recorded in the ROM 302, the RAM 303, the magnetic disk 305, the optical disk 307, etc. described in FIG. It realizes functions such as, image analysis, and transmission of analysis results. Further, the function of the communication unit 113 in FIG. 1 can be realized by using the communication I/F 314 in FIG.

Further, the navigation device 300 may have the function of the image transmission device 101 shown in FIG. In this case, since the navigation device 300 mounted on the user's vehicle described above realizes the function of the image transmitting device 101, the server can be eliminated.

(Calculation of planned route and image analysis processing)
In the first embodiment, an example will be described in which the terminal 111 (navigation device 300) mounted on the vehicle calculates a planned travel route and performs image analysis.

The navigation device 300 guides a route to the destination, for example, a candidate route having a short time or a short distance, based on the current position of the vehicle and the setting of the destination. The user travels by setting one of the candidate routes as a planned route according to time and distance.

Then, when requesting the acquisition of the image at the above-described predetermined position, the navigation device 300 calculates the time to reach the predetermined position on the selected planned route and transmits it to the image transmission device 101 together with the image.

In addition, the navigation device 300 analyzes an image each time the image is captured, and determines the road condition (congestion condition, driving lane, etc.) of the road included in the image. In this image analysis, a range similar to a road in the image is specified by image processing. The road range is specified based on the color of the road surface and the lanes on the road. Further, the driving lane and the traffic jam condition (degree of traffic jam) are specified based on the lanes in the image, the number of other vehicles, the inter-vehicle distance, and the like. At this time, by calculating including the traveling speed, it can be determined that the vehicle is congested (congested) when, for example, a large number of vehicles are photographed in the image in a state where the speed is close to zero.

(Example of database)
FIG. 4 is a chart showing an example of a database recorded in the image transmitting apparatus. 3 shows a database 400 stored in the recording unit 103. The database 400 includes a photographing ID 401 for each photographed image and various image information parameters 402 to 412.

The recording unit 103 assigns an ID 401 to each image received from the terminal 111, and a latitude 402, a longitude 403, a road link ID 404, a shooting date 405, a shooting time 406, a time zone 407, and a traffic jam assigned to the image for each ID 401. The degree 408, the traveling lane 409, the weather 410, the road surface condition 411, and the image data 412 are recorded in the recording unit 103 in association with each other.

The latitude 402 and the longitude 403 are the positions at the time of capturing an image transmitted from the terminal 111. The road link ID 404 is an identifier for each road (link) on the map data included in the terminal 111 (navigation device 300) or the image transmission device 101 (server), and is a road link ID located at the time of image capturing.

The shooting date 405 and the shooting time 406 are the date and time when the image was shot, which was transmitted from the terminal 111. As the time zone 407, a time zone of one day, such as daytime or night, is set based on the photographing time 406.

The congestion degree 408 is a part of analysis information obtained by image analysis of an image captured by the terminal 111 or the image transmission device 101. Also, if there is traffic congestion information at the shooting position without image analysis, it may be acquired from the outside. The congestion degree 408 is set to, for example, smooth, small congestion, medium congestion, large congestion, or the like.

The traveling lane 409 is a part of analysis information obtained by image-analyzing the image captured by the terminal 111 or the image transmission device 101, and for example, 1 lane, left, right, center (lane), etc. are set. .. Further, this information may be used if it can be obtained as the traveling lane 409 based on the position of the vehicle on the map data without image analysis.

As the weather 410, the image transmitting apparatus 101 acquires weather information from the outside, and, for example, weather information at the photographing position, for example, fine, cloudy, rain, heavy rain, snow, fog, etc. is set.

The road surface condition 411 is a part of analysis information obtained by performing image analysis on an image captured by the terminal 111 or the image transmission device 101, and, for example, usually snowfall, freezing, flooding, and the like are set. Further, this information may be used if the road surface condition at the shooting position can be obtained from the outside without image analysis. In the image data 412, the file path to the captured image is set.

Although only parameters for two images are illustrated in FIG. 4, the image transmitting apparatus 101 (server) assigns each image and parameter each time an image is output from the terminal 111 (navigation apparatus 300). The database 400 can be constructed.

Then, the database 400 can be searched for the latitude 402 and the longitude 403 as the requested predetermined position, and the ID 401 whose time 406 matches can be searched, and the image data 412 of this ID 401 can be transmitted to the terminal 111. In addition, the information of other plural parameters 402 to 411 of the corresponding ID 401 can be added and transmitted to the terminal 111.

That is, the terminal 111 (navigation device 300) requests an image at a predetermined position that requests the image transmission device 101, regardless of whether or not the device itself performs the image analysis (for example, the image transmission device 101 side). In doing so, the parameters 402 to 411 can be designated and transmitted. As a result, the image transmitting apparatus 101 can search the database 400 for an image that matches the parameters 402 to 411 specified by the terminal 111.

(Specific example of transmitted image)
FIG. 5 is a table for explaining a method of selecting a combination of database parameters when an image is specified. An example of processing in which the image transmitting apparatus 101 (server) selects an image that matches the position and date and time requested by the terminal 111 will be described.

The image transmitting apparatus 101 selects, from the database 400, the one in which the parameters of the image information acquired for distribution and the parameters 401 to 411 of the image information corresponding to the image data stored in the database 400 are matched, and the terminal 111 is selected. This is the image to be sent.

Then, when there are a plurality of images that match the request of the terminal 111, the latest one of the shooting dates and times 405 and 406 is selected from the parameters and transmitted to the terminal 111.

On the other hand, if there is no image having a parameter that matches the request (position, date and time, etc.) of the terminal 111, the image having a higher value is prioritized to be selected and transmitted. In this example, as a request from the terminal 111, in addition to the time (date 405, time 406) at a predetermined position (latitude 402, longitude 403), the road condition 411, the weather 410, the degree of congestion 408, the time zone from the terminal 111. It is assumed that there is a request for 407 and the traveling lane 409.

In the example shown in FIG. 5, the image transmitting apparatus 101 uses the road surface condition 411, the weather 410, the congestion degree 408, the time zone 407, and the running as the high-value parameters in the order of the highest priority among those described in FIG. Use lane 409.

Then, as shown in FIG. 5, the image transmitting apparatus 101 transmits to the terminal 111 using a priority order according to the parameter matching/mismatching of each image of the database 400 with respect to these high-value parameters requested by the terminal 111. An image (image data 412 corresponding to ID 401 in FIG. 4) is determined.

For example, as the image with the highest priority (priority 1), the image requested by the terminal 111, in which the parameters of the road surface condition 411, the weather 410, the congestion degree 408, the time zone 407, and the driving lane 409 are selected, is selected. To do. For example, in the parameter of priority 2 the parameter of the driving lane 409 having the lowest priority does not match the request of the terminal 111, but in the parameter of the priority 3 the time zone 407 having the higher priority than the driving lane 409. The parameters do not match the request from the terminal 111, and are set as these priorities 2 and 3, respectively.

As described above, even when there is no image having a parameter that matches the request (position, date and time, etc.) of the terminal 111, similarly, when there are a plurality of images under the same condition, the shooting date and time 405 and 406 are set. The latest one is selected and transmitted to the terminal 111.

(Example of Image Shooting to Example 1-Processing of Database Storage)
FIG. 6 is a flowchart illustrating processing contents from image capturing to database storage according to the first embodiment. In the first embodiment, the image captured by the terminal 111 (navigation device 300) is analyzed, and the analysis information is transmitted to the image transmission device 101.

First, the terminal 111 such as a navigation device always measures the current position by GPS or the like (step S601). Then, when the vehicle moves, the date and time and the position (latitude/longitude) of each movement are specified, and the position matching of the vehicle with the traveling road on the map data is performed (step S602).

Then, an image including the road is taken by the camera 112 at a predetermined position (step S603). The photographing position of the photographed image may be periodically set at regular intervals, may be set every time a set position such as an intersection is reached, or may be set at an arbitrary position by a user operation.

After that, the terminal 111 analyzes the captured image (step S604). By this image analysis, the terminal 111 generates road analysis information included in the image. For example, the terminal 111 can obtain the road surface condition 411 at the shooting position, the weather 410, the congestion degree 408, the time zone 407, and the traveling lane 409 by image analysis as described above.

Then, the terminal 111 transmits (uploads) the analysis information to the image transmitting apparatus 101 together with the captured image (and date and time, position) (step S605).

The image transmission device 101 side such as a server receives the image transmitted from the terminal 111 (navigation device 300) and the analysis information (step S611). Then, the received image (and date and time, position) is associated with the analysis information (step S612). Then, the image is stored in the database 400 (step S613) and the analysis information is stored in the database 400 (step S614).

(Example of image transmission processing according to the first embodiment)
FIG. 7 is a flowchart illustrating the processing content of image transmission corresponding to the request according to the first embodiment. For example, the terminal 111 (navigation apparatus 300) performs a route search by setting a destination, performs a process of presenting a planned route from the current location to the destination, and instructs the server (image transmission apparatus 101) for each predetermined guidance point. An example of making an image acquisition request will be described.

First, the terminal 111 always measures the current position by GPS or the like (step S701). Then, when the vehicle moves, the date and time and the position (latitude/longitude) for each movement are specified, and the position matching of the vehicle with the traveling road on the map data is performed (step S702).

Then, when the destination is set by operating the terminal 111 (step S703), the terminal 111 performs a route search (step S704). In this route search, a plurality of planned route candidates from the current position of the vehicle to the destination are calculated, and the optimal planned route is presented according to the settings such as time and distance. At the time of calculating the route, the congestion of the planned route is predicted based on the congestion information. It also predicts passage of a guidance point such as an intersection on the planned route (time, etc.) and processes the lanes (guide lanes) passing on the planned route.

After that, when the vehicle travels on the planned route, the terminal 111 requests the server (image transmitting apparatus 101) to acquire an image every time when reaching the guidance point such as an intersection (step S705). At this time, the terminal 111 transmits to the server (the image transmitting apparatus 101), together with the information of the guide point, the position of the guide point, the date and time of reaching the guide point, the traffic jam prediction of the guide point, the information of the guide lane, and the like. To do. After that, the terminal 111 waits to receive the image data from the server (image transmitting apparatus 101).

On the server (image transmitting device 101) side, when receiving the image acquisition request from the terminal 111 (navigation device 300) (step S711), the database 400 is inquired (step S712). Then, the image data corresponding to the information of the guide point received from the terminal 111 (position of the guide point, date and time to reach the guide point, traffic jam prediction of the guide point, information of the guide lane, etc.) is acquired (step S713), and the terminal It transmits to 111 (step S714).

The terminal 111 acquires the image data transmitted from the server (image transmitting apparatus 101) (step S706) and displays the image data (step S707). The image data to be displayed is image data corresponding to the guidance point requested by the server. At this time, an image corresponding to the guide point information included in the request to the server, for example, an image corresponding to the position of the guide point or the date and time when the guide point is reached can be displayed. In addition, when the image is requested, the traffic congestion prediction of the guide point obtained based on the route search on the side of the terminal 111, the information such as the guide lane, the weather information and the like are transmitted to the server so that the actual arrival at the desired position can be achieved. You will be able to display images that match the situation.

8 to 10 are diagrams showing examples of images displayed by the terminal. 7 is a display example of an image received by the terminal 111 (navigation device 300) from the server (image transmission device 101).

The image shown in FIG. 8 is an example of an image when the road surface is normal, the weather is rainy, the congestion degree is busy, the time zone is daytime, and the driving lane is on the right. The image shown in FIG. 9 is an example in the case where the road surface is normal, the weather is fine, the congestion degree is good, the time zone is night, and the traveling lane is one lane. The image shown in FIG. 10 is an example in which the road surface is frozen, the weather is fine, the degree of congestion is good, the time zone is daytime, and the traveling lane is one lane.

As shown in FIGS. 8 to 10, the position and the arrival date and time of the guidance point requested by the terminal 111 (navigation apparatus 300) to the server (image transmission apparatus 101), the traffic congestion prediction of the guidance point, the guidance lane, By transmitting the information such as the weather, the terminal 111 can receive and display an image suitable for the actual situation when the terminal 111 actually arrives at the desired position from the server (image transmitting apparatus 101).

In addition to the position and the arrival date and time of the guidance point included in the acquisition request from the terminal 111, the image transmission device 101 also obtains from the database 400 an image that matches parameters such as traffic congestion prediction, guidance lane, and weather of the guidance point. It is acquired and transmitted to the terminal 111.

In addition, even when the image transmitting apparatus 101 cannot acquire an image that matches the parameter included in the acquisition request from the database 400, the image transmitting apparatus 101 determines the priority of the valuable information (parameter) as shown in FIG. Based on this, the image to be acquired from the database 400 is determined. For example, in the image shown in FIG. 8, it is assumed that there is no matching image only for the traveling lane requested by the terminal 111. In this case, since the traveling lane 409 shown in FIG. 5 has the lowest priority, an image of priority 2 from which the remaining three parameters (road surface condition 411, weather 410, and time zone 407) match is acquired from the database 400. It is read and transmitted to the terminal 111. This allows the terminal 111 to acquire an image close to the situation when the desired position is reached.

According to the first embodiment described above, the terminal can acquire the image at the desired position from the image transmission device. In particular, the terminal can acquire the image of the time when the terminal reaches the scheduled position before the arrival by specifying the position and the date and time at the time of request. As a result, the terminal can acquire the image that is closest to the predicted situation of the passing date and time of the desired position.

Further, if the terminal is configured to send the information about the desired spot to the server in addition to the image acquisition request, the server can send the image suitable for the acquired information to the terminal. For example, it transmits information about traffic congestion prediction at a guidance point, a guidance lane, weather when arriving, and the like. As a result, the server acquires an image with higher prediction accuracy that matches these pieces of information, that is, an image close to the situation when the terminal actually reached the position requested to be acquired, before the requested position was reached. become able to.

Next, a second embodiment of the present invention will be described. The second embodiment is different from the first embodiment in that the server (the image transmitting apparatus 101) performs the image analysis process. Other configurations and processes are similar to those of the first embodiment.

(Image capture of Example 2 to processing example of database storage)
FIG. 11 is a flowchart illustrating processing contents from image capturing to database storage according to the second embodiment.

First, the terminal 111 such as a navigation device always measures the current position by GPS or the like (step S1101). Then, when the vehicle is moved, the date and time and the position (latitude/longitude) for each movement are specified, and the position of the vehicle is matched with the traveling road on the map data (step S1102).

Then, an image including the road is taken by the camera 112 at a predetermined position (step S1103). The photographing position of the photographed image may be periodically set at regular intervals, may be set every time a set position such as an intersection is reached, or may be set at an arbitrary position by a user operation.

Then, the terminal 111 transmits (uploads) the captured image (and date and time, position) to the image transmitting apparatus 101 (step S1104).

The image transmission device 101 side such as a server receives the image transmitted from the terminal 111 (navigation device 300) (step S1111).

Then, the image transmitting apparatus 101 performs image analysis on the received image (step S1102). By this image analysis, the image transmitting apparatus 101 generates road analysis information included in the image. For example, as described above, the image transmitting apparatus 101 can obtain the road surface condition 411 at the shooting position, the weather 410, the degree of congestion 408, the time zone 407, and the traveling lane 409 by image analysis.

Then, the image transmitting apparatus 101 associates the received image (and date and time, position) with the analysis information (step S1113). Then, the image is stored in the database 400 (step S1114), and the analysis information is stored in the database 400 (step S1115).

(Example of image transmission processing according to the second embodiment)
FIG. 12 is a flowchart illustrating processing details of image transmission corresponding to the request according to the second embodiment. For example, the terminal 111 (navigation apparatus 300) sets a destination, the image transmission apparatus 101 performs a route search, and presents the terminal 111 with a planned route from the current location to the destination. Further, an example will be described in which the image transmitting apparatus 101 transmits an image for each predetermined guidance point on the planned route to the terminal 111.

First, the terminal 111 always measures the current position by GPS or the like (step S1201). Then, when the vehicle is moved, the date and time and the position (latitude/longitude) for each movement are specified, and the position of the vehicle is matched with the traveling road on the map data (step S1202).

Then, when the destination is set by the user's operation or the like (step S1203), the terminal 111 requests the server (image transmitting apparatus 101) for guidance on the route of the planned route (and traffic congestion prediction) (step S1204). .. At this time, the terminal 111 notifies the image transmitting apparatus 101 of information on the current location and the destination.

When the server (image transmitting apparatus 101) receives a guidance request for route guidance (and traffic congestion prediction) from the terminal 111 (step S1211), it performs route search (step S1212). In this route search, a plurality of planned route candidates from the current position of the vehicle to the destination are calculated, and the optimal planned route is presented according to the setting of time, distance, and the like. At the time of calculating the route, the congestion of the planned route is predicted based on the congestion information. It also predicts passage of a guidance point such as an intersection on the planned route (time, etc.) and processes the lanes (guide lanes) passing on the planned route.

Then, the server (image transmitting apparatus 101) generates each piece of information on the route guidance of the planned route, the traffic congestion prediction, the guidance point at the time of traveling, and the guidance lane, and notifies the terminal 111 (step S1213).

When the terminal 111 obtains the route guidance of the planned route, the traffic congestion prediction, the guidance point at the time of traveling, the guidance lane from the server (the image transmission device 101) (step S1205), the planned route of the route guidance and the congestion of the planned route. The information is displayed (step S1206).

Then, when the vehicle travels on the planned route, the terminal 111 requests the server (image transmitting apparatus 101) to acquire an image every time when reaching the guidance point such as an intersection (step S1207). At this time, the terminal 111 transmits to the server (the image transmitting apparatus 101), together with the information of the guide point, the position of the guide point, the date and time of reaching the guide point, the traffic jam prediction of the guide point, the information of the guide lane, and the like. To do. After that, the terminal 111 waits to receive the image data from the server (image transmitting apparatus 101).

On the server (image transmitting device 101) side, when receiving the image acquisition request from the terminal 111 (navigation device 300) (step S1214), the database 400 is inquired (step S1215). Then, the image data corresponding to the information on the guide point received from the terminal 111 (the position of the guide point, the date and time to reach the guide point, the traffic jam prediction of the guide point, the information on the guide lane, etc.) is acquired (step S1216), and the terminal is displayed. It transmits to 111 (step S1217).

The terminal 111 acquires the image data transmitted from the server (image transmitting apparatus 101) (step S1208) and displays this image data (step S1209). The image data to be displayed is image data corresponding to the guidance point requested by the server. At this time, an image corresponding to the guide point information included in the request to the server, for example, an image corresponding to the position of the guide point or the date and time when the guide point is reached can be displayed. In addition, the terminal 111 can acquire information such as traffic congestion prediction, guidance lanes, and weather information at a guidance point based on a route search on the server (image transmission device 101) side when requesting an image. By transmitting to the server (image transmitting apparatus 101) each time it arrives, the terminal 111 obtains from the server (image transmitting apparatus 101) an image that matches the actual situation when actually arriving at the desired position. Can be displayed.

In the first and second embodiments above, the terminal 111 (navigation apparatus 300) side is configured to search for a route to the destination, but the present invention is not limited to this. The terminal 111 transmits the current position and the destination to the server (image transmitting apparatus 101), and the server side searches for a route to the destination on the map data based on the current position and the destination transmitted by the terminal 111 (vehicle). It may be configured to perform processing.

In addition, in the first and second embodiments described above, the terminal 111 uses the position of the guide point, the date and time when the guide point is reached, the traffic jam prediction of the guide point, and the guide as information of the guide point to the server (image transmitting apparatus 101). Although the lane information and the like are transmitted together, the present invention is not limited to this. The terminal 111 is configured to transmit the position of the guide point to the server (the image transmitting apparatus 101) and acquire the date and time when the server side arrives at the guide point, the traffic jam prediction of the guide point, the information of the guide lane, the weather of the guide point, and the like. Good.

According to the second embodiment described above, similarly to the first embodiment, the terminal can acquire the image of the desired position from the image transmitting device, and by specifying the position and the date and time at the time of the request, the terminal can later It becomes possible to acquire an image at the time when the position to pass is reached.

Further, in the second embodiment, since the server side performs the image analysis process, the processing load on the terminal side can be reduced. Then, also in the second embodiment, the terminal can acquire an image close to the situation when the position actually requested to be acquired is reached before reaching the requested position.

The functions of the image transmitting apparatus 101 according to the first and second embodiments may be configured such that a predetermined computer apparatus collects images from the terminal 111 and distributes the images to the terminal 111. For example, the image transmission device 101 is not limited to a specific server, and may be configured using the above-mentioned terminal 111 (navigation device 300).

Further, in the embodiment, the navigation device is used as the terminal, but a terminal such as another smartphone can be used.

As described above, according to the present invention, the image transmission device collects the images of the roads and transmits the images when the requested point is reached before the arrival. As a result, it becomes possible to easily determine the road condition when the vehicle reaches the predetermined position by looking at the image of the predetermined position before reaching the predetermined position. The delivered image is the image that most closely matches the request among the actual images taken in the past, so it is possible to know in advance the road conditions when reaching a predetermined position, and to change the travel route in advance. It will also be possible to take proactive measures such as taking action.

Also, if the route search is configured, it is possible to acquire images of multiple guide points such as intersections on the planned route before reaching the guide point, and the situation of each planned point of the planned route can be displayed by the image. You will be able to judge easily. As a result, it becomes possible to appropriately perform a route re-search.

The image transmission method described in the present embodiment can be realized by executing a prepared program on a computer such as a personal computer or a workstation. This program is recorded on a computer-readable recording medium such as a hard disk, a flexible disk, a CD-ROM, an MO, or a DVD, and is executed by being read from the recording medium by the computer. Further, this program may be a transmission medium that can be distributed via a network such as the Internet.

100 image transmission system 101 image transmission device 102 acquisition unit 103 recording unit 104 transmission unit 111 terminal 112 camera 113 communication unit 114 display unit 121 network 300 navigation device 400 database

Claims (1)

A recording unit in which the image and the position information at which the image is captured are recorded in association with each other;
When an acquisition request for an image taken at a predetermined point is obtained from the terminal, the position of the point at the time when the terminal is associated with the position information corresponding to the predetermined point and the terminal reaches the predetermined point. Transmitting means for transmitting an image suitable for the situation to the terminal,
An image transmission system comprising:

Images