JP2022141724A - Information processing device, measuring instrument and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information processing device and a measuring instrument which can certainly and exactly execute update of a map.

SOLUTION: A server device 4 stores an advanced map DB43 including feature information regarding a feature in a storage unit 42. Then, the server device 4 receives difference information Idf showing difference between the feature information and the actual feature corresponding to the feature information from a plurality of on-vehicle machines 1A, 1B loading an external world sensor which measures the feature. In addition, the server device 4 transmits a raw data request signal SR for requesting transmission of raw data Irw which is measurement data of the actual feature to the on-vehicle machine 1B according to a degree of reliability calculated on the basis of a plurality of pieces of difference information Idf.

SELECTED DRAWING: Figure 3

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to technology for updating map data.

2. Description of the Related Art Conventionally, there has been known a technique for updating map data based on the output of a sensor installed in a vehicle. For example, in Patent Document 1, in a navigation system having a server that manages the latest map data and a navigation device that receives map update information from the server, when a change in map data is detected by a sensor, , a navigation device is disclosed in which settings are made to increase the frequency of map update requests at detected points.

JP 2013-108820 A

2. Description of the Related Art A system is known in which, when each vehicle detects a change point in map data using a sensor, the map data is updated by transmitting data regarding the change point to a server that manages the map data. In such a system, for example, when a predetermined number or more of data of the same or similar change points are received, the server determines that the change points are reliable, and reflects the change point data in the map data. . On the other hand, when the reliability of the change is medium (that is, when it cannot be clearly determined whether or not there has been a change), even though there has been a change, it cannot be reflected in the map data, or the change has not actually occurred. There is a possibility that incorrect changes will be reflected in the map data even though they were not. On the other hand, advanced maps used in autonomous driving must be updated reliably and accurately when changes occur in the map. Patent Literature 1 does not disclose or suggest anything about the above problem.

SUMMARY OF THE INVENTION The present invention has been made, for example, to solve the problems described above, and a main object of the present invention is to provide an information processing apparatus and a measuring apparatus capable of reliably and accurately updating a map. and

The claimed invention is an information processing device, which stores feature information about a feature and a plurality of mobile bodies equipped with a measuring device for measuring the feature and the feature information. a receiving unit that receives difference information indicating a difference from an actual feature corresponding to object information; and a request unit that requests the plurality of moving bodies or other moving bodies.

Further, the invention described in the claims is a measuring device mounted on a moving object, comprising: a measuring unit for measuring the position of an object existing around the moving object; a receiving unit for receiving a transmission request including position information related to the feature from an external device comprising a storage unit for storing feature information related to the feature; a transmitting unit configured to transmit the measurement data stored in the storage unit to the external device after the included position is within a predetermined distance.

Further, the invention described in the claims is a control method executed by an information processing apparatus having a storage unit for storing feature information related to features, wherein a plurality of mobile bodies equipped with measuring devices for measuring features , a receiving step of receiving difference information indicating a difference between the feature information and the actual feature corresponding to the feature information; and a requesting step of requesting the plurality of moving bodies or other moving bodies to transmit measurement data of an object.

Further, the claimed invention is a control method executed by a measuring device mounted on a moving object and having a measuring unit for measuring the position of an object existing around the moving object, wherein the measurement data obtained by the measuring unit a storage step of sequentially storing in a storage unit; a receiving step of receiving a transmission request including position information related to the feature from an external device having a storage unit that stores feature information related to the feature; and a transmission step of transmitting the measurement data stored in the storage unit to the external device after the position of the body and the position included in the transmission request are within a predetermined distance.

It is a schematic structure of an advanced map system. (A) shows the functional configuration of the vehicle-mounted device; (B) shows a functional configuration of a server device; FIG. 3 is a functional block diagram showing a functional relationship between an in-vehicle device and a server device; It is an example of the data structure of difference information. It is an example of the data structure of a raw data request signal. It is an example of the data structure of raw data information. It is an example of the flowchart which shows the processing procedure which concerns on an Example. Shows a data structure containing a raw data request.

According to a preferred embodiment of the present invention, an information processing apparatus includes a storage unit that stores feature information related to features, and a plurality of moving bodies equipped with measuring devices that measure features, and stores the feature information and relevant information from a plurality of moving bodies. a receiving unit for receiving difference information indicating a difference from the actual feature corresponding to the feature information; and transmitting the measurement data of the actual feature in accordance with the reliability calculated based on a plurality of pieces of the difference information. to the plurality of moving bodies or other moving bodies.

The information processing device includes a storage unit, a reception unit, and a request unit. The storage unit stores feature information related to features. The receiving unit receives difference information indicating a difference between feature information and an actual feature corresponding to the feature information from a plurality of mobile bodies equipped with measuring devices for measuring features. The request unit requests a plurality of mobile bodies or other mobile bodies to transmit actual feature measurement data according to the reliability calculated based on the plurality of pieces of difference information. According to this aspect, the information processing device acquires and analyzes the measurement data of the target feature from the moving body, and accurately determines the change of the feature, regarding the feature that may change, based on the difference information. can do.

In one aspect of the information processing device, the measurement data has a larger capacity than the difference information. According to this aspect, the information processing apparatus can appropriately determine changes in features while appropriately suppressing an increase in communication traffic associated with transmission and reception of unnecessary measurement data.

In another aspect of the information processing device, the feature information is updated when the reliability exceeds a predetermined upper limit, and the feature information is updated when the reliability is less than a predetermined lower limit. and the request unit requests transmission of the measurement data when the reliability is equal to or less than the upper limit value and equal to or more than the lower limit value. According to this aspect, the information processing apparatus suitably suppresses an increase in the amount of communication associated with the transmission and reception of unnecessary measurement data, and even if it is not possible to accurately determine the change in the feature only with the difference information, the measurement data can be used. Based on this, it is possible to accurately determine changes in features.

In another aspect of the information processing apparatus, the request unit requests transmission of the measurement data when the number of the difference information necessary for calculating the reliability cannot be received within a predetermined period. According to this aspect, the information processing apparatus can accurately determine the change of the feature based on the measurement data even when the necessary number of difference information cannot be collected and the presence or absence of the change of the feature cannot be accurately determined. can.

In another aspect of the information processing device, the measurement data is three-dimensional data generated by a rangefinder that emits laser light. According to this aspect, the information processing device can accurately determine whether or not there is a change in the feature based on the measurement data.

According to another preferred embodiment of the present invention, there is provided a measuring device mounted on a moving object, comprising: a measuring unit for measuring the position of an object existing around the moving object; a receiving unit for receiving a transmission request including position information related to the feature from an external device having a storage unit for storing and a storage unit for storing feature information related to the feature; a transmitting unit that transmits the measurement data stored in the storage unit to the external device after the position included in the transmission request is within a predetermined distance. In this aspect, when the measuring device receives a transmission request including position information related to features from an external device that manages feature information, the external device preferably performs analysis, etc. regarding changes in feature information. Measurement data of the feature of interest can be transmitted to an external device for execution.

In one aspect of the measuring device, the storage unit updates the measurement data when the position of the moving object changes. According to this aspect, the measuring device can suitably suppress redundant measurement data measured at the same point from being stored in the storage unit.

In another aspect of the measuring device, the storage unit stores a plurality of measurement data corresponding to a plurality of different positions of the moving body, and when the position of the moving body changes, , one piece of measurement data stored for the longest period of time is erased, and one piece of new measurement data by the measurement unit is stored. According to this aspect, the measuring device can store the measurement data generated when the vehicle travels within the latest predetermined distance in the storage unit.

According to another preferred embodiment of the present invention, there is provided a control method executed by an information processing apparatus having a storage unit for storing feature information relating to features, comprising: a receiving step of receiving, from a mobile object, difference information indicating a difference between feature information and an actual feature corresponding to the feature information; and a requesting step of requesting the plurality of moving bodies or other moving bodies to transmit actual feature measurement data. By executing this control method, the information processing device acquires and analyzes the measurement data of the target feature from the moving object, and analyzes the feature that may change based on the difference information. Changes can be determined accurately.

According to another preferred embodiment of the present invention, there is provided a control method executed by a measuring device mounted on a moving object and having a measuring unit that measures the position of an object existing around the moving object, the measuring unit a storage step of sequentially storing measured data in a storage unit; and a receiving step of receiving a transmission request including position information related to the feature from an external device having a storage unit that stores feature information related to the feature. and a transmission step of transmitting the measurement data stored in the storage unit to the external device after the position of the mobile body and the position included in the transmission request are within a predetermined distance. By executing this control method, the measuring device receives a transmission request including position information related to features from an external device that manages feature information. Measurement data of the target feature can be transmitted to an external device so that analysis or the like can be performed appropriately.

In a preferred example, the program causes a computer to function as any one of the information processing devices or measuring devices described above. The computer preferably functions as the information processing device or the measuring device described above by executing the program described above.

Preferred embodiments of the present invention will be described below with reference to the drawings.

[System configuration]
FIG. 1 is a schematic configuration of an advanced map system according to this embodiment. The advanced map system includes a plurality of vehicle-mounted devices 1 (1A, 1B, . . . ) equipped with external sensors for measuring features, and a server device 4 that stores an advanced map DB 43. FIG. Then, the advanced map system appropriately updates the information (also referred to as "feature information") related to features such as the position and shape of features around the road registered in the advanced map DB 43 .

The in-vehicle device 1 has one or more external sensors such as Lidar (Light Detection and Ranging, or Laser Illuminated Detection and Ranging) and cameras, and highly accurately estimates the position of the vehicle based on the output of the external sensor. etc.

In this embodiment, the in-vehicle device 1 detects a difference in the feature information registered in the advanced map DB 43 based on the output of the external sensor, and outputs information about the detected difference (also referred to as "difference information Idf"). Send to the server device 4 . Further, when the in-vehicle device 1 receives a signal (also referred to as a “raw data request signal SR”) requesting unprocessed data (so-called raw data) output by an external sensor, the raw data request signal SR is specified. Information (also referred to as “raw data information Irw”) on the raw data including the position to be detected in the detection target range is transmitted to the server device 4 . Hereinafter, for convenience of explanation, the vehicle-mounted device 1 that transmits the difference information Idf will be referred to as the "vehicle-mounted device 1A", and the vehicle-mounted device 1 that transmits the raw data information Irw based on the raw data request signal SR will be referred to as the "vehicle-mounted device 1B". call. Note that the vehicle-mounted device 1 mounted on each vehicle may actually have the functions of both the vehicle-mounted device 1A and the vehicle-mounted device 1B. The in-vehicle device 1 is an example of a "measuring device" in the present invention.

The server device 4 stores an advanced map DB 43 containing feature information corresponding to each feature existing around the road, and distributes part or all of the advanced map DB 43 in response to a request from the vehicle-mounted device 1 . Features registered as feature information in the advanced map DB 43 include, for example, kilo-posts lined up periodically along the road, 100-m posts, delineators, traffic infrastructure facilities (e.g. signs, direction signs, traffic lights), utility poles, and streetlights. In addition to artificial features such as , natural features such as trees may be used. In this embodiment, the server device 4 determines whether or not there is a change in the feature information registered in the advanced map DB 43, based on the difference information Idf received from the vehicle-mounted device 1A. At this time, the server device 4 calculates the reliability of the difference information Idf (also referred to as “reliability Rdf”), and transmits the raw data request signal SR to the vehicle-mounted device 1 according to the calculated reliability Rdf. When receiving the raw data information Irw based on the raw data request signal SR, the server device 4 analyzes the raw data included in the raw data information Irw, and updates the feature information registered in the advanced map DB 43. Determine the necessity and update contents. The server device 4 is an example of an "information processing device" and an "external device" in the present invention.

[Configuration of in-vehicle device and server device]
FIG. 2A is a block diagram showing the functional configuration of the vehicle-mounted device 1. As shown in FIG. The in-vehicle device 1 mainly includes a communication section 11 , a storage section 12 , a sensor section 13 , an input section 14 , a control section 15 and an output section 16 . These elements are interconnected via bus lines.

Under the control of the control unit 15 , the communication unit 11 performs data communication such as difference information Idf, raw data request signal SR, raw data information Irw, etc. with the server device 4 . The communication unit 11 also receives map data including feature information from the server device 4 under the control of the control unit 15 .

The storage unit 12 stores programs executed by the control unit 15 and information necessary for the control unit 15 to execute predetermined processing. For example, the storage unit 12 stores map data including feature information received from the communication unit 11 .

Further, in this embodiment, the storage unit 12 of the vehicle-mounted device 1B stores the raw data generated in the most recent traveling section of a predetermined distance in the raw data cache 21 for temporarily storing the raw data. As will be described later, every time the vehicle travels a predetermined distance, the control unit 15 acquires the latest raw data from the external sensor 31, along with information on the time when the raw data was acquired, the position of the vehicle, and the attitude of the vehicle. It is linked and stored in the raw data cache 21. - 特許庁At this time, information about the position, type, and setting conditions of the external sensor 31 used to generate the raw data may also be stored in the raw data cache 21 . In this case, the raw data cache 21 deletes the raw data stored for the longest period and newly stores the latest raw data based on the first-in, first-out method. In this way, the control unit 15 accumulates raw data according to the traveled distance instead of accumulating raw data according to time, so that the raw data generated at the same place when the vehicle stops is used as the raw data. Duplicate accumulation in the cache 21 can be preferably suppressed.

The sensor unit 13 includes one or more external sensors 31 for measuring features existing around the vehicle, a GPS receiver 32 , a gyro sensor 33 , an acceleration sensor 34 and a speed sensor 35 . The external sensor 31 measures features such as a rider and a camera that exist around the vehicle, and outputs the measurement data to the control unit 15 . For example, a lidar discretely measures the distance to an object existing in the external world by emitting a pulsed laser over a predetermined angular range in the horizontal and vertical directions, and creates a three-dimensional image showing the position of the object. Output point cloud information as measurement data. The camera also outputs captured image data generated at predetermined intervals to the control unit 15 . The external sensor 31 is an example of a "measurement section" in the present invention.

The input unit 14 is a button, a touch panel, a remote controller, a voice input device, etc. for user operation.

The control unit 15 includes a CPU that executes programs and the like, and controls the entire in-vehicle device 1 . For example, the control unit 15 causes the communication unit 11 to transmit to the server device 4 a request signal for map data specifying the vehicle position predicted based on the output of the GPS receiver 32, etc. is received by the communication unit 11 and stored in the storage unit 13 . In addition, the control unit 15 performs transmission processing of the difference information Idf, reception processing of the raw data request signal SR, and transmission processing of the raw data information Irw via the communication unit 11. ” function.

FIG. 2B is a block diagram showing the functional configuration of the server device 4. As shown in FIG. The server device 4 mainly includes a communication section 41 that performs data communication with the vehicle-mounted device 1 under the control of the control section 45 , a storage section 42 , and a control section 45 . These elements are interconnected via bus lines.

The storage unit 42 stores programs executed by the control unit 45 and information necessary for the control unit 45 to execute predetermined processing. In this embodiment, the storage unit 42 stores an advanced map DB 43 . The advanced map DB 43 includes feature information corresponding to each feature to be detected by the external sensor 31 of the vehicle-mounted device 1 . Further, the storage unit 42 accumulates the difference information Idf and the raw data information Irw received from the plurality of vehicle-mounted devices 1 under the control of the control unit 45, as will be described later.

The control unit 45 includes a CPU that executes programs and the like, and controls the entire server device 4 . For example, when a request signal for map data is received by the communication unit 41, the control unit 45 extracts from the advanced map DB 43 map data including feature information around the position indicated by the position information included in the request signal. and transmits it to the in-vehicle device 1 that is the source of the request. Further, in this embodiment, the control unit 45 functionally includes a difference information receiving unit 46, a raw data requesting unit 47, and a map updating unit 48, which will be described later.

[Map update process]
Next, details of the updating process of the advanced map DB 43 will be described.

(1) Functional Block FIG. 3 is a functional block diagram showing the functional relationship between the vehicle-mounted device 1 (1A, 1B) and each element of the server device 4. As shown in FIG.

The difference information receiving unit 46 receives, from the communication unit 41, the difference information Idf indicating the change of the feature from the vehicle-mounted device 1A that has detected the change of the feature whose feature information is registered in the advanced map DB 43. FIG. Here, the difference information Idf does not include the measurement data of the feature, etc., and has a smaller data volume than the raw data information Irw. The difference information Idf also includes feature identification information (also referred to as “feature ID”), so that it is possible to identify which feature the information is related to. The difference information receiving section 46 is an example of the "receiving section" in the present invention. Note that the vehicle-mounted device 1A may transmit the difference information Idf indicating the detection result of the feature based on the output of the external sensor 31 to the difference information receiving unit 46 regardless of whether or not a change in the feature is detected. good. In this case, the difference information Idf includes information as to whether or not the difference of the target feature has been detected.

The raw data requesting unit 47 calculates the reliability Rdf based on the difference information Idf for each feature stored in the storage unit 42 . In this case, the raw data requesting unit 47, for example, estimates the parameter for which the detection process was performed for each feature, and based on the ratio of the difference information Idf indicating the disappearance or change of the feature to the parameter Calculate the reliability Rdf. In this case, the raw data requesting unit 47 counts the vehicle-mounted devices 1 that have passed through a route on which the target feature can be detected by referring to the position information or the like that is periodically received from each vehicle-mounted device 1 . A parameter may be calculated, or the above parameter may be estimated by referring to the statistical traffic volume of the route. In another example, when the difference information Idf is transmitted even when there is no change in the feature, the raw data requesting unit 47 calculates the above parameter based on the number of received difference information Idf. You may In another example, the raw data requesting unit 47 may calculate the corresponding reliability Rdf based only on the number of pieces of difference information Idf indicating the disappearance or change of features. In yet another example, information indicating the type of the external sensor 31 or the type of vehicle used in the feature detection process, which is included in the received difference information Idf, is identified, and detected by the specific type of external sensor 31 or vehicle. The reliability Rdf may be calculated by weighting the difference information Idf obtained, or based only on the difference information Idf detected by the external sensor 31 of a specific type or the vehicle.

Then, when the raw data requesting unit 47 determines that it is necessary to analyze the raw data information Irw based on the calculated reliability Rdf and the like to analyze in detail whether or not there is a change in the feature information, the vehicle-mounted device 1B Send raw data request signal SR. In this case, as will be described later, the raw data request signal SR includes the position information of the feature to be detected. In this case, for example, the raw data requesting unit 47 transmits the raw data request signal SR to the vehicle-mounted device 1B located within a predetermined distance from the position where the feature requiring the raw data information Irw exists. Note that the raw data requesting unit 47 specifies the position of each vehicle unit 1, for example, by receiving position information from each vehicle unit 1 traveling on the road at predetermined intervals.

Here, the transmission timing of the raw data request signal SR will be supplementarily explained using a specific example.

For example, when the reliability Rdf is equal to or less than a predetermined upper threshold (also referred to as a "first threshold") and equal to or greater than a predetermined lower threshold (also referred to as a "second threshold"), the raw data requesting unit 47 , determines that it is necessary to analyze in detail whether or not there is a change in the feature information, and transmits a raw data request signal SR. For example, the above-described first threshold is a threshold for determining whether or not the difference information Idf is reliable information, and the above-described second threshold is a threshold for determining whether the difference information Idf is unreliable information. This is a threshold for determining whether or not it can be determined. The first threshold is an example of a "predetermined upper limit" in the present invention, and the second threshold is an example of a "predetermined lower limit" in the present invention.

In another example, the raw data requesting unit 47 did not collect the necessary number of difference information Idf for calculating the reliability Rdf within a predetermined period from among the features whose information is registered in the advanced map DB 43. If a feature exists, a raw data request signal SR designating the position of the feature is transmitted. In yet another example, when the raw data requesting unit 47 receives notification information from the in-vehicle device 1 indicating that it has detected that the road in the map data is different from the actual road, the raw data requesting unit 47 designates a position around the road. raw data request signal SR.

In response to the raw data request signal SR, the raw data requesting unit 47 receives raw data information Irw including raw data obtained by measuring the target feature from the vehicle-mounted device 1B via the communication unit 41 . The raw data requesting unit 47 then stores the received raw data information Irw in the storage unit 42 . The raw data requesting section 47 is an example of a "requesting section" in the present invention.

The map updating unit 48 updates the feature information in the advanced map DB 43 based on the raw data information Irw stored in the storage unit 42 . For example, when a predetermined number or more of raw data information Irw targeting the same feature are accumulated in the storage unit 42, the map updating unit 48 analyzes the accumulated raw data information Irw to update the corresponding geographical feature. Determine whether or not an object has changed. Then, if the map updating unit 48 determines that the position, shape, etc. of the target feature has been changed or disappeared based on the analysis result, the feature information of the target feature registered in the advanced map DB 43 is changed based on the analysis results. The map update section 48 is an example of the "update section" in the present invention.

Here, a supplementary description will be given of the processing when the vehicle-mounted device 1B receives the raw data request signal SR.

For example, when the detection target range of the external sensor 31 is in the forward direction of the vehicle, the vehicle-mounted device 1B approaches within a predetermined distance from the position indicated by the position information included in the raw data request signal SR. A part or all of the raw data stored in the raw data cache 21 is extracted and transmitted to the server device 4 as raw data information Irw. The aforementioned predetermined distance is set, for example, within the range of the detectable distance of the external sensor 31 and at a distance necessary and sufficient for detecting the object. In another example, when the detection range of the external sensor 31 includes the rear or side direction of the vehicle, the vehicle-mounted device 1B moves away from the vehicle by a predetermined distance or more after passing the position indicated by the position information included in the raw data request signal SR. Sometimes, part or all of the raw data stored in the raw data cache 21 is extracted and transmitted to the server device 4 as raw data information Irw. The vehicle-mounted device 1B immediately transmits the raw data information Irw when the condition of approaching within a predetermined distance from the position indicated by the position information included in the raw data request signal SR or moving away from the position by a predetermined distance or more after approaching is met. Alternatively, it may be sent at any timing after the conditions are met.

According to these examples, the in-vehicle device 1B can suitably transmit to the server device 4 raw data including a feature existing at the position specified by the raw data request signal SR. Furthermore, the in-vehicle device 1B transmits the raw data information Irw including the raw data generated at a plurality of positions stored in the raw data cache 21, so that the target feature is temporarily placed in the blind spot of a stopped vehicle or the like. , and even if the target feature is not included in the raw data information Irw, the server device 4 can preferably statistically detect the position, shape, etc. of the feature from a plurality of raw data. .

(2) Data Structure Next, specific examples of the data structures of the difference information Idf, the raw data request signal SR, and the raw data information Irw will be described.

(2-1) Difference Information FIG. 4 is an example of a data structure of difference information Idf generated by the vehicle-mounted device 1A when detecting a change in a feature. The feature information IF shown in FIG. 4 includes header information and body information.

The header information includes fields of "header ID", "version information", "time information when difference is detected", "own vehicle position information when difference is detected", and "own vehicle attitude information when difference is detected". Identification information indicating the difference information Idf is registered in the “header ID”. The version of the data structure of the body information is registered in the "version information". "Time information at time of difference detection", "Vehicle position information at time of difference detection", and "Vehicle posture information at time of difference detection" are time information when the change of the feature (i.e. difference) was detected. , position information, and attitude information of the vehicle are registered. In this case, the in-vehicle device 1 calculates the roll angle, pitch angle, and yaw angle of the vehicle at the time of feature detection based on detection signals from internal sensors such as the gyro sensor 33 and the acceleration sensor 34, and Information on these angles is registered in the "vehicle attitude information at the time of difference detection".

The body information includes fields of "feature ID", "change identification flag", and "sensor type information". Identification information of a unique feature assigned in the advanced map DB 43 is registered in the "feature ID". The feature ID may be composed of a plurality of IDs that specify the target feature in stages. For example, the feature ID of "road sign A" may be composed of an ID representing the type of "road sign" and an ID representing "A", which is a kind of road sign. In this case, these IDs may be registered in different fields.

A flag indicating a change is registered in the "change identification flag". For example, a flag indicating that the target feature has disappeared, a flag indicating that the position of the target feature has changed, a flag indicating that the target feature has been transformed, etc. are registered in the "change identification flag". be done. Information indicating the type of the external sensor 31 used for the feature detection process is registered in the "sensor type information". Instead of or in addition to the "sensor type information", "vehicle type information" indicating the type of vehicle may be provided.

As described above, since the difference information Idf does not have a field for registering data with a large data volume, the data volume is smaller than the raw data information Irw including the measurement data (raw data) of the external sensor 31 .

(2-2) Raw Data Request Signal FIG. 5 shows an example of the data structure of the raw data request signal SR. In the example of FIG. 5, the raw data request signal SR includes "header ID" and "version information" indicating the raw data request signal SR as header information, and "position information" and "version information" as body information. raw data transmission conditions”.

Here, in the "positional information", information specifying a point from which the raw data information Irw is to be obtained (that is, the position of the feature to be determined whether or not there is a change) is registered. Preferably, in addition to the "location information" field, a "feature ID" field is further provided.

Information defining the conditions for acquiring the raw data information Irw is registered in the "raw data transmission conditions". Here, the "raw data transmission condition" includes subfields of "vehicle position condition", "running speed condition", "time period condition", and "sensor condition". In the "vehicle position condition", conditions related to the position of the vehicle at the time of acquisition of the raw data information Irw are registered. designation etc. is registered. In the "running speed condition", a vehicle speed condition (for example, x ("x" is a positive number) km/h or less) at the time of acquisition of the raw data information Irw is registered. In the "time period condition", the time period condition for obtaining the raw data information Irw is registered.

The "sensor condition" registers conditions related to the external sensor 31 that generates raw data to be included in the raw data information Irw, and is composed of subfields of "sensor type condition" and "sensor data condition". Information defining the type of the external sensor 31 (for example, rider or camera) that generates the raw data information Irw is registered in the "sensor type condition". In the "sensor data condition", conditions such as settings when generating raw data for the external sensor 31 specified in the sensor type condition are registered. For example, in the case of a lidar, the "sensor data conditions" include the fact that only point cloud information of an object at a distance of y (y is a positive number) meters or more should be sent as raw data, and only point cloud information with a predetermined brightness or higher is registered as raw data. Furthermore, as a "sensor condition", a subfield may be provided for designating the positional condition of the external sensor 31 used to generate the raw data when the external sensor 31 exists at a plurality of positions in the vehicle. That is, in the "sensor condition", the external sensor 31 that generates the raw data and the information that designates the conditions related to its setting are registered.

A field such as a "raw data transmission request flag" storing flag information indicating whether or not the raw data information Irw is necessary (for example, "1" if necessary and "0" if not necessary) is added to the body. information may be provided.

(2-3) Raw Data Information FIG. 6 shows an example of the data structure of raw data information Irw generated by the vehicle-mounted device 1B that has received the raw data request signal SR. The feature information IF shown in FIG. 6 includes header information and body information.

The header information consists of fields of "header ID", "version information", "time information when raw data is obtained", "own vehicle position information when raw data is obtained", and "own vehicle attitude information when raw data is obtained". including. Identification information indicating the raw data information Irw is registered in the "header ID". The version of the data structure of the body information is registered in the "version information". "Time information when raw data was obtained", "Vehicle position information when raw data was obtained", and "Vehicle attitude information when raw data was obtained" are the time when the raw data included in the body information was generated. Information, location information, and vehicle attitude information are registered.

The body information includes fields of "raw data type ID", "raw data size", and "raw data". Identification information indicating the type of raw data or identification information indicating the type of the external sensor 31 that outputs the raw data is registered in the "raw data type ID". Size information of raw data registered in "Raw data" is registered in "Raw data size". Raw data extracted from the raw data cache 21 is registered in "raw data".

(3) Processing Flow FIG. 7 shows a process flow of a vehicle-mounted device 1A that generates difference information Idf, a server device 4, and a vehicle-mounted device 1B that receives a raw data request signal SR from the server device 4 and generates raw data information Irw. It is a flow chart which shows each processing procedure. The vehicle-mounted device 1A, the server device 4, and the vehicle-mounted device 1B repeatedly execute the processing of the flowchart shown in FIG.

First, the vehicle-mounted device 1A detects the current position, attitude, speed, etc. of the vehicle based on outputs from the GPS receiver 32, the gyro sensor 33, the acceleration sensor 34, the speed sensor 35, etc. (step S11).

Next, the in-vehicle device 1A performs feature detection processing based on the output of the external sensor 31 (step S12). In this case, for example, the vehicle-mounted device 1A identifies a feature existing around the current position predicted in step S11 based on the feature information stored in the storage unit 12, and detects the feature based on the output of the external sensor 31. process. In this case, for example, the vehicle-mounted device 1A periodically receives map data including feature information around the vehicle position from the server device 4, so that the map data is registered in the advanced map DB 43. The storage unit 12 stores feature information having the same contents as the feature information obtained.

Then, the vehicle-mounted device 1A determines whether or not there is a change in the feature to be detected (step S13). In this case, for example, the vehicle-mounted device 1A stores the position, shape, etc. of the feature specified based on the current position predicted in step S11 and the output of the external sensor 31, and the feature indicated by the feature information stored in the storage unit 12. By comparing the position, shape, etc., it is determined whether or not a change in the position or shape of the target feature, a disappearance of the target feature, or the like has occurred. When the in-vehicle device 1A determines that there is a change in the feature to be detected (step S13; Yes), it generates difference information Idf and transmits it to the server device 4 (step S14). On the other hand, when the vehicle-mounted device 1A determines that there is no change in the feature to be detected (step S13; No), the process returns to step S11. Note that even if the vehicle-mounted device 1A determines that there is no change in the detection target feature, the information indicating that the detection target feature has not may be transmitted to the server device 4 together with the . The difference information Idf in this case is used, for example, to calculate the reliability Rdf.

The server device 4 receives and accumulates the difference information Idf transmitted from the vehicle-mounted devices 1A of a plurality of vehicles (step S21). Then, the server device 4 executes the following steps S22 to S27 for each feature for which the difference information Idf is accumulated.

The server device 4 determines whether or not the accumulated difference information Idf indicates that the difference information Idf has disappeared and the reliability Rdf has exceeded the first threshold (step S22). Then, if the server device 4 determines that the stored difference information Idf has disappeared and the reliability Rdf has exceeded the first threshold (step S22; Yes), it determines that the difference information Idf is reliable. , the advanced map DB 43 is updated (step S27). Specifically, in this case, the server device 4 deletes the feature information related to the target feature from the advanced map DB 43, or adds information indicating that the feature has disappeared to the feature information.

On the other hand, if the accumulated difference information Idf indicates a change other than disappearance, or if the reliability Rdf is equal to or less than the first threshold (step S22; No), the server device 4 determines whether or not the raw data request condition is met. (step S23). For example, when the reliability Rdf is less than the second threshold, the server device 4 determines that the corresponding difference information Idf has low reliability and does not satisfy the raw data requirement. In another example, the server device 4 determines that the raw data requirement is satisfied when the stored difference information Idf indicates a change other than erasure and the reliability Rdf is equal to or higher than the second threshold. In yet another example, the server device 4 determines that the raw data request condition is satisfied when the accumulated difference information Idf indicates disappearance and the reliability Rdf is equal to or less than the first threshold and equal to or more than the second threshold. In still another example, the server device 4 determines that the raw data requirement is satisfied when the number of pieces of difference information Idf required for calculating the reliability Rdf is not collected.

Then, when the server device 4 determines that the raw data request condition is satisfied (step S23; Yes), the raw data request signal SR designating the position of the target feature exists in the peripheral position of the target feature. is transmitted to the vehicle-mounted device 1B (step S24). On the other hand, when the server apparatus 4 determines that the raw data requirement is not satisfied (step S23; No), the process returns to step S21.

The in-vehicle device 1B mounted on each vehicle traveling on the road stores raw data for a predetermined travel distance output from the external sensor 31 in the raw data cache 21 (step S31). Then, when receiving the raw data request signal SR from the server device 4, the vehicle-mounted device 1B stores the information of the raw data request position indicated by the raw data request signal SR (step S32). In the example of FIG. 5, the vehicle-mounted device 1B stores the information registered in the "position information" of the body information as the information of the request position of the raw data described above.

Then, the vehicle-mounted device 1B determines whether or not the vehicle is traveling around the requested position of the raw data stored in step S32 (step S33). Then, when it is determined that the vehicle-mounted device 1B is traveling around the raw data request position (step S33; Yes), among the raw data stored in the raw data cache 21, The raw data information Irw including the raw data corresponding to the information registered in the "raw data transmission condition" of the body information received is transmitted to the server device 4 (step S34). On the other hand, if the vehicle-mounted device 1B determines that it is not traveling around the raw data request position stored in step S32 (step S33; No), the process returns to step S31, and the raw data cache 21 continues to store external data in the raw data cache 21. Raw data of sensor 31 is stored.

On the other hand, the server device 4 determines whether or not it has received a predetermined number or more of raw data information Irw for each feature to which the raw data request signal SR has been sent (step S25). The above-mentioned predetermined number is set to the number of pieces of raw data information Irw required to detect a feature by, for example, known image analysis, statistical analysis, or the like for the raw data information Irw. When the server device 4 determines that the raw data information Irw of the predetermined number or more has been received (step S25; Yes), the server device 4 performs analysis processing for feature detection targeting the received raw data information Irw. Then, it is determined whether or not the target feature has actually changed (step S26). On the other hand, when the server device 4 determines that only the raw data information Irw less than the predetermined number has been received (step S25; No), it continues to perform the raw data information Irw reception process.

Then, if the server device 4 determines that there has actually been a change in the target feature based on the analysis of the raw data information Irw (step S26; Yes), the advanced map DB 43 is updated (step S27). On the other hand, when the server device 4 determines that the target feature has not actually changed based on the analysis of the raw data information Irw (step S26; No), the processing of the flowchart ends.

As described above, the server device 4 according to the present embodiment stores the advanced map DB 43 including feature information about features in the storage unit 42 . Then, the server device 4 receives difference information Idf indicating the difference between the feature information and the actual feature corresponding to the feature information from the plurality of vehicle-mounted devices 1 equipped with the external sensors 31 that measure the features. do. In addition, the server device 4 sends a raw data request signal SR requesting transmission of raw data, which is actual feature measurement data, to the vehicle-mounted device 1 according to the reliability Rdf calculated based on the plurality of pieces of difference information Idf. Send. According to this aspect, the server device 4 obtains raw data of the target feature from the vehicle-mounted device 1 and analyzes it in detail based on the difference information Idf. can be accurately determined.

Here, a supplementary description will be given of the effect of collecting the raw data information Irw and updating the advanced map DB 43 .

In general, the difference information Idf transmitted by each vehicle-mounted device 1A is information determined independently by each vehicle-mounted device 1A, and thus may include data based on erroneous detection. Therefore, the server device 4 according to the present embodiment can suitably calculate the reliability Rdf for the difference information Idf by collecting and analyzing the difference information Idf of the same point of the plurality of vehicle-mounted devices 1A. In this case, for example, the server device 4 updates the advanced map DB 43 when the reliability Rdf exceeds the upper limit first threshold, and updates the advanced map DB 43 when the reliability Rdf is less than the lower limit second threshold. do not update. Then, the server device 4 distributes the updated advanced map DB 43 to each vehicle-mounted device 1 again, so that the vehicle-mounted device 1 can always use the latest map.

On the other hand, in a place where the environment dynamically changes, the reliability Rdf becomes equal to or less than the first threshold and equal to or more than the second threshold, and a situation may occur in which it is impossible to determine whether or not the difference information Idf can be trusted. In such a case, since the raw data is measurement data obtained by capturing the real world without processing, the server device 4 collects the raw data information Irw from each vehicle-mounted device 1B to perform more detailed analysis. It is possible to determine whether or not there is a change in the feature. On the other hand, since the amount of raw data is usually large, the server device 4 receives the minimum required amount of raw data by transmitting a raw data request signal SR designating the required portion of the raw data to the in-vehicle device 1B. . As a result, the amount of communication data can be suitably reduced.

[Modification]
Instead of transmitting the raw data request signal SR, the server device 4 may embed information to the effect that the raw data is requested in the map data distributed to the vehicle-mounted device 1 .

FIG. 8A is an example of a data structure of feature information in which information indicating a request for raw data can be embedded.

In the example of FIG. 8A, the body information of the feature information is provided with an "attribute information" field, and the "attribute information" is provided with a "reliability" subfield. In this case, for example, the server device 4 sets the subfield of "reliability" of the feature information for which the raw data information Irw is required to "Unknown". In this case, the in-vehicle device 1B that has received the map data from the server device 4 refers to the target feature information, and since the subfield of "reliability" is set to "Unknown", the target feature information is It is determined that the reliability of the object is unknown and that raw data information Irw needs to be transmitted. Then, the in-vehicle device 1B transmits the raw data information Irw including the raw data stored in the raw data cache 21 to the server device 4 when passing through the vicinity of the position indicated by the position information of the target feature information.

In another example, a table that can arbitrarily specify points requiring raw data may be defined as attribute information of route information representing links and nodes. FIG. 8B is an example of the data structure of the above table.

In the example of FIG. 8B, the header information is provided with a "link ID or node ID" field, and the corresponding link ID or node ID is registered. Also, the body information is provided with fields of "location information format information", "size information", and a plurality of (here, n) "location information" fields. Here, in the "location information format information", identification information in the format of information stored in the "location information" (for example, a format represented by latitude and longitude or a location reference format) is registered. Information on the number of fields in the "position information" (here, n) is registered in the "size information". "Position information" registers the position information of a feature for which raw data is required or the position information specifying the measurement position.

In this case, the server device 4 includes the table of FIG. Then, the in-vehicle device 1B that has received the table of FIG. 8B generates raw data based on the position designated by the "position information" of the body information, and sends the raw data information Irw including the raw data to the server device. 4. As in the embodiment, the server device 4 may transmit the table of FIG. 8(B) as the raw data request signal SR to the vehicle-mounted device 1A running on the target route or its surrounding routes. .

1 In-vehicle device 4 Server device 11, 41 Communication unit 12, 42 Storage unit 13 Sensor unit 14 Input unit 15, 45 Control unit 16 Output unit 31 External sensor 43 Advanced map DB

Claims (1)

a storage unit that stores feature information about features;
a receiving unit that receives difference information indicating a difference between feature information and an actual feature corresponding to the feature information from a plurality of mobile bodies equipped with measuring devices that measure features;
a request unit that requests the plurality of moving bodies or other moving bodies to transmit the actual feature measurement data according to the reliability calculated based on the plurality of pieces of difference information;
An information processing device comprising:

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