WO2015051718A1 - Dynamic track navigation method and cloud platform - Google Patents
Dynamic track navigation method and cloud platform Download PDFInfo
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- WO2015051718A1 WO2015051718A1 PCT/CN2014/087686 CN2014087686W WO2015051718A1 WO 2015051718 A1 WO2015051718 A1 WO 2015051718A1 CN 2014087686 W CN2014087686 W CN 2014087686W WO 2015051718 A1 WO2015051718 A1 WO 2015051718A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C21/00—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00
- G01C21/26—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00 specially adapted for navigation in a road network
- G01C21/34—Route searching; Route guidance
- G01C21/3453—Special cost functions, i.e. other than distance or default speed limit of road segments
- G01C21/3492—Special cost functions, i.e. other than distance or default speed limit of road segments employing speed data or traffic data, e.g. real-time or historical
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C21/00—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00
- G01C21/26—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00 specially adapted for navigation in a road network
- G01C21/34—Route searching; Route guidance
- G01C21/3446—Details of route searching algorithms, e.g. Dijkstra, A*, arc-flags, using precalculated routes
Definitions
- the invention belongs to the field of navigation, and in particular relates to a dynamic track navigation method and a cloud platform.
- Road segments, nodes, definitions of shape points and static traffic restrictions In the actual situation, in order to avoid excessive consideration of the topological relationship between roads, the road intersection in the road network map is generally extracted as the object of analysis, and the intersection is defined as one of the nodes, and the node may also include the end of the road. Or where the road property changes; at the same time, the road is segmented by nodes, and a section of the road between the two nearest nodes is defined as a road segment. In this way, the entire road network map will be composed of nodes and road segments.
- the intersection points are the nodes of the network
- the road segments are the arcs of the network
- several interconnected road segments with the same name form a road.
- the road segment can be described by a broken line, and the apex at the turning point of the polyline is called a road shape value point.
- the shape value point exists on the road segment, and the portion between the two adjacent shape value points is called the sub-section of the road segment.
- Static traffic restriction information refers to fixed traffic restrictions that do not change over a long period of time in an actual transportation network: single-line, no turning, no U-turn. To process this information, it is first necessary to establish a model of the road topology relationship and to obtain a representation of the static traffic restriction information so that the information can be integrated into the traffic network model and can be easily identified and stored by the system.
- Real-time traffic information collection Previously, the acquisition of traffic information relied mostly on traffic flow detection equipment on the road, such as ring induction coils, radar, video photos, license plate recognition, infrared sensors and floating vehicles (FC).
- traffic flow detection equipment such as ring induction coils, radar, video photos, license plate recognition, infrared sensors and floating vehicles (FC).
- FC floating vehicles
- mobile terminals have been used to collect road condition information.
- a large number of taxi trajectories are used to enrich real-time traffic information, especially as a main source of information for real-time road conditions.
- Forecast of road traffic conditions Since the traffic condition information is changing, if the traveler selects the route according to the traffic information before his departure, perhaps when he arrives at an intersection, the road that should have been smooth has become overcrowded. Therefore, real-time prediction of the traffic conditions of the road in a certain period of time is crucial for precise navigation. At present, the research on this aspect is not effective.
- the object of the embodiments of the present invention is to provide a cloud platform central control type dynamic trajectory navigation method, which aims to solve the problem that the prior art cannot directly apply the trajectory information to the quantitative calculation of path planning, resulting in unreasonable path planning and reaction road conditions.
- the problem of change insensitivity at the same time, it provides a new method for predicting congestion road conditions, and can calculate a path planning scheme with the shortest travel time based on the predicted result; and this prediction method is based on the upload of the relevant mobile terminal.
- the terminal has been derived from a real-time path planning scheme, so the prediction method is relatively reliable when the number of related mobile terminals is sufficient.
- a dynamic navigation path planning method comprising:
- the cloud platform receives multiple track information uploaded by multiple mobile terminals in real time or multiple real-time path planning schemes of multiple terminals, and then uses the multiple track information or multiple terminals to have a real-time path planning solution to update and improve the cloud platform.
- Internal dynamic road segment database Internal dynamic road segment database
- the cloud platform When the cloud platform receives a specific path planning request from the mobile terminal, the cloud platform calculates a path plan with a specific requirement according to the dynamic road segment database data in the updated and improved cloud platform. Requesting a corresponding path plan, and then transmitting the corresponding path plan to the mobile terminal in a wireless manner;
- the trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the trajectory belongs;
- the number of trajectories refers to consecutive two-dimensional or three-dimensional spatial position coordinate points uploaded by each mobile terminal within the statistical time range and spatial range Forming a trajectory in a chronological order from first to last, and then accumulating the number of the trajectories to obtain a quantity;
- the real-time path planning scheme of the terminal refers to a driving plan that is already existing in the mobile terminal and is in use, from the location to the destination when the mobile terminal starts this uploading, which can tell the cloud platform Where does the mobile terminal start, which way to go, and where it will go; the main role is to predict the congestion of the road in the future, which is constantly changing as the mobile terminal continues to move; in fact, it It is also similar to a trajectory--a trajectory that may be formed in the future; it does not refer to the path plan that the cloud platform makes to the mobile terminal and will send to the mobile terminal.
- T1v the time when the vehicle No. 1 reaches the node V
- T1vw(t1v) the vehicle No. 1 arrive at the node W.
- Tpnvw also known as the dynamic impedance of the segment vw from V to W in the T-time region.
- time zone T is the elapsed time corresponding to the existing trajectory information, it is the instantaneous dynamic impedance; if the time zone T is a specified future time zone, then the future time zone T and the terminal are used.
- the dynamic impedance calculated by the real-time path planning scheme and the historical data of the cloud platform is called the predicted dynamic impedance.
- a dynamic segment database real-time uploaded trajectory information of multiple mobile terminals and the terminal's existing real-time path planning scheme, generate and update new road segments, generate and update simulated traffic restriction information, generate and update instantaneous dynamic impedance, generate and Updating the predicted dynamic impedance, such a dynamic database of related segments.
- the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating road segment data on an unknown road, generating and updating real-time dynamic impedance of all road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. , generation and Updating simulated traffic restriction information of all road segments, and generating and updating predicted dynamic impedances of all road segments according to the existing real-time path planning scheme and trajectory historical data of the plurality of terminals;
- the all the road segments are included in the newly generated road segment and the original road segment;
- the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory;
- the acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- a cloud platform in a second aspect, includes multiple smart devices, and the smart device includes: a processor, a memory, a communication interface, and a bus;
- the communication interface wirelessly receives multiple track information uploaded by multiple mobile terminals or multiple real-time path planning schemes of multiple terminals in real time, and the processor then uses the multiple track information or multiple terminals to have an existing real-time path planning scheme to update And perfecting the dynamic link database inside the cloud platform; when the communication interface receives a path planning request with specific requirements proposed by the mobile terminal, the processor calculates the dynamic road segment database data according to the updated and improved cloud platform. And corresponding a path planning request with a specific path planning request, and then transmitting the corresponding path planning to the mobile terminal in a wireless manner;
- the trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the trajectory belongs;
- the number of trajectories refers to consecutive two-dimensional or three-dimensional spatial position coordinate points uploaded by each mobile terminal within the statistical time range and spatial range Forming a trajectory in a chronological order from first to last, and then accumulating the number of the trajectories to obtain a quantity;
- the real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal to go from the place where the uploading starts to the destination;
- the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating the traffic restriction information, and generating and updating the predicted dynamic impedance of all the road segments according to the existing real-time path planning scheme and the trajectory historical data of the plurality of terminals;
- the all the road segments are included in the newly generated road segment and the original road segment;
- the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory;
- the acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- the technical solution provided by the present invention has the advantages of realizing large-scale use of the mobile terminal to collect track information for dynamic traffic information and accurately and reasonably navigate.
- FIG. 1 is a flowchart of a dynamic navigation path planning method according to an embodiment of the present invention
- FIG. 2 is a schematic structural diagram of a cloud platform according to an embodiment of the present invention.
- One of the most significant inventive aspects of the present invention is to change the solid-state road segment database within the navigation system to a dynamic road segment database that changes as the trajectory information changes.
- a real-time path planning scheme of a terminal of a plurality of mobile terminals is uploaded to the cloud platform center in real time, and is calculated according to the existing real-time path planning scheme of the terminal and historical data in the cloud platform. Predict dynamic impedance, used to predict future road congestion conditions and calculate path planning.
- the invention can be said to be a product of cloud computing, big data, mobile internet, car networking, and Beidou navigation era. Because the number of uploaded pieces of trajectory information described in the present technology refers to the so-called massive, large data order of magnitude, that is to say, the plurality of trajectory information refers to a massive amount of tens of thousands or more Orderly, continuous, dense trajectory information flow, only in this case, the correlation calculation with the number of trajectories will have a good effect.
- One of the most significant inventive aspects of the present invention is to transfer the main body of the path planning from the original mobile terminal to a control center, inside the cloud platform system, and change the usually solid state road segment database within the cloud platform system to the track information.
- Dynamic and dynamic segment database with changes at the same time, this technology uses cloud computing technology, uses massive trajectory information, and calculates so-called big data according to statistical principles, using the number of trajectories and trajectory acquisition time as important parameters.
- a cloud computing platform wirelessly receives all mobile terminals loaded by the customer on the vehicle in real time, that is, a positioning device with communication function (such as taxi positioning). Tracking information sent by the monitoring device or navigation device (such as a smart phone), then processing and computing, dynamically updating the road segment database inside the cloud platform, generating real-time dynamic impedance weights and predicting dynamic impedance weights, or generating new road segments The new traffic restriction information is generated by the simulation.
- the cloud platform calculates a path plan according to the updated dynamic link database data, and then sends the path plan to the mobile terminal.
- the main technical principle of the specific implementation is as follows: the received trajectory information is discarded, and the Kalman filter processing is performed to remove the noise, and then the original road segment data in the GIS is projected. If successful, the trajectory information is included in the trajectory information.
- the time data changes the instantaneous dynamic impedance weight of the road segment; if it is unsuccessful, the temporary road segment is additionally generated and stored in the road segment database and generates an instantaneous dynamic impedance weight.
- the shortest path is first obtained according to the conventional shortest path algorithm (such as A * algorithm), and the newly generated road segments can be included in the n shortest paths, and then in the n path planning.
- the path planning with the shortest overall time is selected, that is, the shortest time path planning.
- the predicted dynamic impedance of a certain road segment at a certain time in the future can be calculated and applied to the calculation of some path planning.
- the cloud platform is a cloud computing platform, which refers to a network-based, massive storage and computing resource with dynamic storage and computing capabilities, dynamically deployable on demand, dynamically optimized, and dynamically reclaimed.
- the plurality of mobile terminals in the present technology actually refers to a mass of tens of thousands or more than 100 million mobile terminals, where the track information uploaded by one mobile terminal is defined as one track information, and multiple tracks Information refers to massive, tens of thousands or more orders of magnitude and continuous dense trajectory information flow. It is only possible to complete such complicated computing tasks by using such a cloud platform with superior computing power. .
- the embodiment of the present invention has the beneficial effects that the data used in the present invention is comprehensive, continuous, and complicated.
- Massive trajectory information because of the large sample size, so the credibility is high; its collection, storage and calculation, and path planning are carried out inside a cloud platform, with large amount of calculation and fast speed; and it has dynamic and can be used on the map.
- There is no new road to implement navigation can use the trajectory information to update the traffic restriction information, can dynamically calculate the overall path planning time-consuming, real-time reaction to the change of road conditions; in addition, according to many related multiple movements
- the terminal that the terminal is using has a real-time path planning scheme to predict the congestion status of a certain road segment at a certain time in the future.
- the specific embodiment of the present invention provides a dynamic navigation path planning method, which is shown in FIG. 1 and includes:
- the cloud platform receives multiple track information uploaded by multiple mobile terminals or multiple real-time path planning schemes of multiple terminals in real time, and then uses the multiple track information or multiple terminals to have an existing real-time path planning solution, which is updated and improved.
- Dynamic road segment database inside the cloud platform
- the cloud platform When the cloud platform receives a path planning request with a specific requirement by the mobile terminal, the cloud platform calculates and selects a specific requirement according to the dynamic road segment database data in the updated and improved cloud platform.
- the path plan requests a corresponding path plan, and then the corresponding path plan is sent to the mobile terminal in a wireless manner;
- the real-time path planning scheme of the foregoing terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;
- the trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the track belongs;
- the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating the traffic restriction information, and generating and updating the predicted dynamic impedance of all the road segments according to the existing real-time path planning scheme and the trajectory historical data of the plurality of terminals;
- the all the road segments are included in the newly generated road segment and the original road segment;
- the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory;
- the acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- the number of the trajectories refers to a continuous two-dimensional or three-dimensional spatial position coordinate point uploaded by each mobile terminal in a chronological time range and a spatial range, forming a trajectory in a chronological order from first to last. Then, the number of the track segments is accumulated, and the obtained number is obtained.
- the real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal to go from the place where the upload starts to the destination.
- the foregoing method for generating and updating road segment data on an unknown road includes: when a plurality of mobile terminals are traveling on an unknown road, and the uploaded track information cannot be matched to the original road segment data in the dynamic road segment database of the cloud platform.
- the cloud platform discards the trajectory information on the original road segment in the dynamic road segment database that cannot be matched to the cloud platform, discards the abnormal point, removes the noise, and merges and merges into a simulated road according to a certain method, and temporarily stores it into the dynamic road segment.
- the number of trajectories in the simulated road is simultaneously calculated; when the number of trajectories merged on this simulated road reaches a certain threshold within a certain time interval, the cloud platform will The simulated road is transformed into one or several new temporary or permanent newly generated road segment data, which is stored in the dynamic road segment database, and the cloud platform also continuously updates the newly generated road segment data according to the newly uploaded new track information; It is noted that the noise removal can be implemented by a Kalman filter algorithm.
- Method A The cloud platform calculates the average time consuming of the trajectory of a certain time zone on a certain road segment according to the number of trajectories uploaded by the mobile terminal in real time and the acquisition time of the trajectory, and uses the average time consuming as an instant
- the dynamic impedance is stored in a database, and the certain road segment is a road segment on the original road or a newly generated road segment on the unknown road;
- the cloud platform is based on the dynamic road segment database data inside the updated and improved cloud platform. Calculating a path planning request with specific requirements The corresponding path planning specifically includes: the cloud platform uses the database data including these instantaneous dynamic impedances to calculate the path plan with the shortest overall time consumption.
- the cloud platform stores the acquisition time of the trajectory uploaded by the plurality of mobile terminals that are driven on the original road and the unknown road into a dynamic database of the cloud platform, and the acquisition time of the trajectory corresponds to the acquisition time of the trajectory.
- the road segment is associated; when the mobile terminal sets a time zone, and makes a request: when some track acquisition time stored in the dynamic database falls into the time zone, find the trajectory corresponding to the acquisition time, and then Find the road segments where the corresponding trajectories are located, and then use these road segments to splicing out a path plan, and the cloud platform calculates the path plan according to the requirements of the mobile terminal using the qualified road segments.
- Method C The cloud platform stores the number of tracks on a certain road segment uploaded by a plurality of terminals in a database of the cloud platform, and is associated with the corresponding road segment; when the mobile terminal sets a threshold number, and proposes a track on some road segments When the quantity falls into the threshold of the quantity, the road sections are found out, and then the request of the path planning is spliced by the road sections, and the cloud platform splices out the path plan according to the request of the mobile terminal according to the conditional road section.
- mode B and the mode C that is, select a road segment having a certain number of tracks within a certain period of time to splicing the path planning.
- One of the significance of this is that it can avoid some road sections that are closed due to maintenance or accidents, because in this case, the number of vehicle tracks in these closed time zones is obviously trending. At zero. The existing technology is not identifiable for this common situation.
- the foregoing method further includes between 101 and 102:
- the simulation By checking the number of trajectories on a certain time zone and a certain road section of the unknown road and the original road, the simulation generates a prohibition of allowing turning, turning traffic restriction information, allowing U-turn, prohibiting U-turn traffic restriction information or one-way traffic restriction information.
- the simulation generation allows the turning or prohibiting the turning traffic restriction information includes: the cloud platform checks whether the two intersecting road sections have a continuous trajectory of a certain traveling direction formed by the same mobile terminal, and calculates in a set time zone. The number of such trajectories or the relative number of the trajectories compared with the relevant trajectories. When the calculation result is greater than a predetermined value, the simulated generation of the intersections between the two road segments according to the trajectory direction The traffic restriction information that can be turned is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulated generation of the intersection between the two links is prohibited according to the direction of the trajectory. Turn traffic restrictions are stored in a special database.
- the foregoing simulation generation allows the U-turn or the U-turn traffic restriction information to include: the cloud platform checks whether a certain road segment has a forward and reverse trajectory continuously formed by the same mobile terminal with a shape point as a turning point, and calculates a set time zone The number of such trajectories in the domain, or the relative number of the trajectories compared with the relevant trajectories. When the calculation result is greater than a predetermined value, the simulation between the generated segments can be turned according to the trajectory at the turning point.
- the traffic restriction information of the direction U-turn is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulation generates a prohibition between the road segments at the turning point according to the direction of the trajectory turning. Traffic restriction information is stored in a special database.
- the above-mentioned simulation generates single-line traffic restriction information, including: the cloud platform checks the number of tracks formed by the mobile terminal in a certain direction of a certain road segment, and calculates the number of such tracks in a set time region, or the same direction The relative number of comparisons of other or related trajectories. When the result of the calculation is less than a predetermined value, the traffic restriction information of the prohibited passage in the direction of the road segment is simulated and stored in a special database. .
- the foregoing cloud platform calculates, according to the updated and improved data of the dynamic link database in the cloud platform, a corresponding path plan, including:
- the cloud platform first uses the static conventional shortest path calculation method to calculate the path planning scheme with the shortest overall distance, and then selects the shortest path with the shortest time according to the instantaneous dynamic impedance on the road segment in the n shortest path planning scheme.
- Planning, the road section includes: original roads and road sections on unknown roads.
- the above static conventional shortest path calculation method refers to a method called: A * heuristic search algorithm; the algorithm is used to calculate the dynamic road segment database data based on the updated and improved cloud platform.
- the A * heuristic search algorithm includes a special case of the A * heuristic search algorithm with a lower bound of 0: the dijkstra algorithm.
- the foregoing updating and perfecting the road segment database in the cloud platform by using the trajectory information means that the new road segment data generated by the trajectory information simulation is stored together with the original road segment data in a neighboring table manner. In the database.
- the cloud platform calculates the corresponding path plan according to the updated and improved road segment database data, and specifically includes:
- the elevation and 2D or 3D motion direction information in the trajectory information are associated with the road segment and weighted and averaged, and then stored in the database together with the video and photo data to distinguish the approximate road segment; when the cloud platform includes the viaduct, the height is different. However, when some similar sections of the horizontal plane are similar or identical, or other similar heights but the horizontal positions are close to each other, the cloud platform checks the latitude and longitude coordinates of the approximate road segment nodes, and the longitude coordinates of the corresponding nodes of the two road sections. When the absolute value of the difference between the value difference and the latitude coordinate value is less than a set value at the same time, automatically reading the trajectory of the mobile terminal traveling on the two road segments may include the average elevation, the traveling direction, the video, and the photo.
- Information it is also possible to simultaneously calculate the connection relationship between the two road segments and the respective adjacent road segments, and mark and prompt, and store them together in the dynamic road segment database, and the cloud platform is based on the trajectory stored in the dynamic road segment database.
- Information and articulation, computing path planning; then the mobile terminal can be The trajectory information including the average elevation, the driving direction, the video, the photo, and the connection relationship together with the mark and the prompt are sent to the mobile terminal together with the calculated path planning solution; the calculating the connection relationship refers to accumulating on a certain road segment The number of consecutive trajectories formed by each mobile terminal on a straight line or a turn, traveling across a node to an adjacent road segment, when the number falls within a set threshold time within a set time period, or when In a set time zone, when the ratio of the continuous trajectory is compared with the number of related trajectories and the ratio falls within a set threshold, it is confirmed that the two sections have the direction in which the trajectory runs. Cohesion.
- the foregoing uses the trajectory information and the existing real-time path planning scheme of the terminal to update and improve the dynamic path inside the cloud platform.
- the segment database refers to the real-time path planning scheme of the terminal that is dynamically uploaded by the cloud platform according to the dynamics of multiple mobile terminals, and the instantaneous dynamic impedance of the relevant segment of the road segment, and calculates a certain section of the road at a specified time in the future. a predicted quantity of the mobile terminal, and then finding a weighted average of the instantaneous dynamic impedance of the road segment corresponding to the quantity stored in the cloud platform according to the predicted quantity, as the predicted dynamics of the road segment The impedance is stored in a database of the cloud platform along with the corresponding time.
- the cloud platform predicts the traffic congestion of a specified time segment and a specified road segment according to the predicted dynamic impedance. The situation, and calculate a path planning scheme according to the requirements of the mobile terminal, and wirelessly transmit to the mobile terminal.
- the cloud platform calculates, according to the updated and improved road segment database data, the corresponding path plan specifically includes:
- the method of updating and perfecting and calculating the path planning method can combine the technical solutions provided by the above methods as needed.
- the data of the link database in the cloud platform is exactly the same as that of the mobile terminal, and the mobile terminal directly splices the corresponding corresponding road segment according to the path planning scheme made by the cloud platform;
- the map in the cloud platform and the map in the mobile terminal are different versions of the system, or although the data in the road segment database is different from the same version of the system, the main problem is that there are some segments on the cloud platform but the mobile terminal map is No, in order to solve this problem, the special database design and topology relationship should be established in advance, so as to make the two sections of the same system different versions of the database have high compatibility, so that the cloud platform can pass the detection and will jointly own
- the continuous road segment data information is sequentially arranged and sent to the terminal, and then the mobile terminal performs according to the method in a. above; for the part of the cloud platform that is not in the mobile terminal, the cloud platform will use the data in the part of the road segment.
- the latitude and longitude data of the location point is sent to the mobile terminal, and the mobile terminal further finds the corresponding location point according to the latitude and longitude data, and connects and displays it in the display screen, and prompts in the voice prompt: “Unknown road, please press the track Information is carefully driven.”
- the road segment information will be converted into track information according to international or national relevant standards, that is, all path planning schemes will be sent to the mobile terminal in the form of track position point latitude and longitude data, and the mobile terminal is on the screen. According to this, draw a connection for the driver's reference, accompanied by a voice prompt: "Track navigation, please drive carefully according to the trajectory.” This will help maximize the service to a variety of different customers.
- the trajectory information described above may be trajectory information collected by a satellite positioning technology using a GPS/DR, BD2 (second generation Beidou navigation system)/DR mobile terminal positioning module, and a mobile communication base station positioning technology. It may also be an trajectory information acquired by using an electronic identification technology such as an RFID recognition technology, an infrared or a laser scanning technology to identify an electronic tag loaded on the vehicle, and may also include trajectory information acquired by video and image information, The way the track information is collected should not be limited by the acquisition method.
- the trajectory information and the collection of the real-time path planning scheme of the terminal may be acquired anonymously.
- the uploading of the trajectory information between the mobile terminal and the cloud platform or the reception of the path planning may also be performed in a variety of ways, including satellite communication, SMS communication of the Beidou satellite navigation system, WiFi, GPRS, 2G, 3G or 4G technologies.
- the specific embodiments of the present invention are not limited to any wireless communication method.
- the trajectory information may include: longitude, latitude, elevation, two-dimensional or three-dimensional velocity, two-dimensional or three-dimensional motion direction, number of trajectories, code of the mobile terminal to which the trajectory belongs, video and image a parameter, and an acquisition time of the plurality of parameters;
- the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating a plurality of parameters in the trajectory information including the number of trajectories and the acquisition time region of the trajectory And update road segment data on unknown roads, instantaneous dynamic impedance on all road segments, and simulated traffic restriction information on all road segments.
- the cloud platform after receiving the trajectory information, the cloud platform first filters the trajectory to remove the clutter with abnormal or excessive deviation, and then according to a certain method, the position data in the trajectory information is the same as the original in the GIS database.
- Some road segments have data matching. If they succeed, they fall into the data of the road segment.
- the data of the point corresponding to the track and the link segment is changed to the data of the corresponding point of the link, and the instantaneous dynamic impedance weight of the segment is given according to the acquisition time of the track.
- the segment prediction dynamic impedance can be generated and updated according to the existing real-time path planning scheme of multiple terminals.
- the real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal from the location where the uploading starts to the destination; the instantaneous dynamic impedance refers to the received
- the trajectory information of the plurality of mobile terminals is used to calculate the weighted average time of a certain time zone of a certain road segment, and the result is the instantaneous dynamic impedance of a certain section of the certain time zone; the predicted dynamic impedance refers to uploading according to multiple mobile terminals.
- the multiple terminals have a real-time path planning scheme, and combine the historical data in the cloud platform to calculate the time consumption of a certain section of the future time zone, and the result is the predicted dynamic impedance of a certain section of the future time zone; All road segments are those that include newly generated road segments and original road segments.
- the trajectory acquisition time described in the present application refers to a time set formed by the acquisition time of each location point constituting the trajectory
- the acquisition time of the location point refers to that the mobile terminal collects the When the latitude and longitude data is located, there may be an error in the time when the mobile terminal is located and the time at which the data is collected. Therefore, the acquisition time generally lags slightly behind the time at which the mobile terminal is actually located. However, in this technique, this time difference is generally ignored.
- the traffic restriction information described in the present technology includes: prohibiting a turn to the left, prohibiting a turn to the right, prohibiting a U-turn, prohibiting a straight-line traffic prohibition sign information, turning left, turning right, allowing U-turn, one-way road only traffic signs information.
- the cloud platform predicts the traffic congestion condition of a certain specified time and a certain road section according to the predicted dynamic impedance, and calculates a path planning scheme according to the requirements of the mobile terminal, and transmits the data to the mobile terminal wirelessly; the meaning is also: To predict and coordinate the traffic distribution of the vehicle.
- the cloud platform and the mobile terminal collect the transmission speed of the trajectory information, the calculation speed of the path planning scheme and the wireless transmission speed are fast enough, and supplemented by the relevant vehicles.
- the direct communication of the trajectory information can also be used to prevent collisions between vehicles by means of automatic alarm and automatic evasion.
- the calculating the connection relationship refers to accumulating the number of continuous trajectories formed when each mobile terminal on a certain road segment travels to the adjacent road segment during the straight or turning process.
- the value of the quantity, or the relative value of the quantity compared with the number of other related trajectories is greater than a set value within a set time zone, it is confirmed that the two road sections are spanned
- the node is a joint point, and there is a cohesive relationship in the direction in which the trajectory runs; when the value of the quantity, or the relative value of the quantity compared with the number of other related trajectories, is less than one in a set time zone
- setting the value it is true It is considered that the two sections are connected by the nodes they cross, and there is no connection relationship in the direction in which the trajectory runs.
- there is no connection relationship here including the physical conditions such as the road of the upper and lower layers of the overpass. Limits on guardrails and gullies; also include restrictions on traffic rules that are
- the embodiment of the present invention further provides a cloud platform, which includes: a plurality of smart devices, the smart device may specifically be: a computer or a server, and the hardware structure diagram of the smart device is as shown in FIG. 2, including: a processor 201. Memory 202, communication interface 203, and bus 204.
- the processor 201, the memory 202, and the communication interface 203 are connected to each other through a bus 204.
- the bus 204 may be an Industry Standard Architecture (ISA) bus or a Peripheral Component Interconnect (PCI) bus.
- the above-mentioned processor 201 may be a general-purpose processor, including a central processing unit (English: central processing unit, CPU for short), a network processor (English: network processor, referred to as NP), and of course, may also be a digital signal processor (English: Digital Signal Processing, referred to as DSP).
- a central processing unit English: central processing unit, CPU for short
- a network processor English: network processor, referred to as NP
- DSP Digital Signal Processing
- the memory 202 is configured to store a program and a dynamic link database.
- the program can include program code, the program code including computer operating instructions for instructing the processor 201 to issue computer operating instructions.
- the memory 202 may include a high-speed random access memory (RAM) memory, and may also include a non-volatile memory such as at least one disk memory.
- the communication interface 203 is configured to receive or send data.
- the data may be: a packet, a track information, or a path planning information.
- the communication interface 203 may be a communication port, and the communication port includes but is not limited to a wireless communication port or a wired communication port.
- the communication interface 203 wirelessly receives multiple track information uploaded by multiple mobile terminals in real time or has a real-time path planning scheme for multiple terminals, and the processor 201 then updates the existing track path plan by using the multiple track information or multiple terminals. And perfecting the dynamic link database inside the cloud platform; when the communication interface 203 receives a certain path planning request that is requested by the mobile terminal, the processor 201 is configured according to the dynamic segment database data inside the cloud platform that is updated and improved. Calculating a path plan corresponding to a path planning request with a specific requirement, and then transmitting the corresponding path plan to the mobile terminal in a wireless manner;
- the real-time path planning scheme of the foregoing terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;
- the trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the track belongs;
- the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating traffic restriction information, and generating and updating all the roads according to the existing real-time path planning scheme and trajectory history data of the plurality of terminals The predicted dynamic impedance of the segment;
- the all the road segments are included in the newly generated road segment and the original road segment;
- the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory;
- the acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- the processor 201 is configured to: when the track information uploaded by the multiple mobile terminals cannot match the original road segment data in the dynamic road segment database of the cloud platform, the processor 201 removes the track information that cannot match. Noise, according to a certain method, merged into one or more simulated roads, and temporarily stored in the dynamic road segment database, and accumulate the number of tracks in the simulated road; when in a certain time interval, a certain simulation When the number of tracks on the road is added to a certain threshold, the processor converts the simulated road into one or several new temporary or permanent newly generated road segment data, and stores the data in the dynamic road segment database, and the processor 201 The newly generated road segment data is also continuously updated according to the new track information uploaded in real time.
- the processor 201 is specifically configured to calculate, according to the number of trajectories uploaded by the mobile terminal in real time and the acquisition time of the trajectory, an average time consuming of the trajectory of a certain time zone on a certain road segment, and average the trajectory
- the time-consuming is stored as a real-time dynamic impedance in a database, and the certain road segment is a road segment on the original road or a newly generated road segment on the unknown road;
- the processor calculates a certain specific according to the dynamic road segment database data inside the updated and improved cloud platform.
- the corresponding path planning request corresponding path planning specifically includes: the processor uses the database data including the instantaneous dynamic impedance to calculate the overall shortest path planning.
- the processor 201 is specifically configured to store, in a dynamic database of the cloud platform, an acquisition time of the trajectory uploaded by the plurality of mobile terminals that are used on the original road and the unknown road, and acquire the trajectory of the trajectory and the The acquisition time of the trajectory is associated with the road segment; when the mobile terminal sets a time zone, and makes a request: when some trajectory acquisition time stored in the dynamic database falls into the time zone, it is found that the acquisition time corresponds to The trajectory is further found out the path segment where the corresponding trajectory is located, and then a path plan is spliced by using the road segments, and the processor 201 calculates the path plan according to the request of the mobile terminal by using the qualified road segment.
- the processor 201 stores the number of tracks on a certain road segment uploaded by the plurality of terminals in a database of the cloud platform, and is associated with the corresponding road segment; when the mobile terminal sets a threshold number, and proposes to be on some road segments When the number of trajectories falls within the threshold of the number, the road segments are found, and then the request for path planning is spliced by the road segments, and the processor 201 splices out the path plan according to the request of the mobile terminal.
- the processor 201 is specifically configured to simulate to allow turning, prohibit turning traffic restriction information, allow U-turn, and prohibit U-turn traffic by checking the number of tracks on a certain time zone and a certain road section of the unknown road and the original road. Restrict information or one-way traffic restrictions.
- the processor 201 is specifically configured to check whether two intersecting road segments have a continuous trajectory of a certain traveling direction formed by the same mobile terminal, and calculate an absolute number of such trajectories in a set time region. Or the relative quantity compared with the relevant trajectory.
- the simulation generates traffic restriction information between the two road sections that can be turned according to the trajectory direction of the intersecting node.
- Stored in a special database Conversely, when the result of this calculation is less than a predetermined value, the simulated generation of the intersection between the two links is prohibited according to the direction of the trajectory. Turn traffic restrictions information to a special database.
- the processor 201 is specifically configured to check whether a certain road segment has a forward and reverse trajectory continuously formed by the same mobile terminal with a shape point as a turning point, and calculate the trajectory in a set time zone.
- the traffic restriction information is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulation generates a traffic restriction between the road segments that prohibits the U-turn in the turning direction of the turning point. Information is stored in a special database.
- the processor 201 is specifically configured to check the number of tracks formed by the mobile terminal in a certain direction of a certain road segment, and calculate the absolute number of such tracks in a set time region, or the same direction The relative number of comparisons of other or related trajectories. When the result of the calculation is less than a predetermined value, the traffic restriction information of the prohibited passage in the direction of the road segment is simulated and stored in a special database. .
- the processor 201 is specifically configured to calculate a path planning scheme with the shortest overall distance by using a static conventional shortest path calculation method, and then select, according to the instantaneous dynamic impedance on the road segment, the n shortest path planning schemes.
- a path plan with the shortest overall time consuming, the road segments include: original roads and road sections on unknown roads.
- the static conventional shortest path calculation method refers to an A * heuristic search algorithm; and the A * heuristic search algorithm is used to dynamically update the dynamic road segment database data according to the cloud platform.
- the path planning scheme with the shortest overall distance is calculated; the A * heuristic search algorithm includes a special case of the A * heuristic search algorithm with a lower bound of 0: the dijkstra algorithm.
- the updating and improving the dynamic link database in the cloud platform by using the plurality of trajectory information refers to: after the new link data generated by the trajectory information is simulated, the new link data is combined with the original link data. Stored in a database expressed in a contiguous table.
- the processor 201 is specifically configured to associate the elevation and the two-dimensional or three-dimensional motion direction information in the trajectory information with the road segment and weight the average, and store the information in the dynamic road segment database; when the cloud platform uses the upper and lower bridges including the viaduct When the height is different but the horizontal planes are similar or identical, or other similar sections with the same height but close horizontal position are used for path planning, the cloud platform first checks the latitude and longitude coordinates of the approximate road segment nodes, and the longitude coordinates of the corresponding nodes of the two road segments.
- the average elevation and the traveling direction of the trajectory traveling thereon are automatically read, and the connection relationship with the adjacent road segments is calculated and marked.
- the calculating the connection relationship with the adjacent road segments refers to calculating the same mobile terminal
- the absolute number and relative number of consecutive trajectories spanning adjacent segments in the same direction, when The number and relative amount of the fall threshold number is set in a time region is set, it is confirmed for both engagement sections has a relationship in the direction of the running track.
- the using the trajectory information or the existing real-time path planning scheme of the terminal to update and improve the dynamic road segment database inside the cloud platform refers to the real-time path planning of the terminal that is dynamically uploaded by the cloud platform according to dynamics of multiple mobile terminals.
- the solution, and the instantaneous dynamic impedance within a certain period of time of the road segment involved calculate a predicted number of mobile terminals on a certain road segment at a specified time in the future, and then find the stored and stored in the cloud platform according to the predicted quantity.
- the predicted quantity corresponds to a certain one of the road segments
- the weighted average of the instantaneous dynamic impedance during the segment time is used as the predicted dynamic impedance of the road segment, and the predicted dynamic impedance is stored together with the corresponding time in the dynamic road segment database of the cloud platform, when a mobile terminal proposes a specific path
- the cloud platform predicts the traffic congestion condition of a specified time and a specified road section according to the predicted dynamic impedance, and calculates a path planning solution according to the requirement of the specific terminal planning of the mobile terminal, and sends the path planning plan to the mobile terminal.
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Abstract
A dynamic navigation path planning method and a cloud platform, which are applicable to the field of navigation. The method comprises: receiving, by a cloud platform, multiple pieces of track information uploaded by a plurality of mobile terminals in real time and wirelessly or existing real-time path planning solutions of a plurality of terminals; then, using the multiple pieces of track information or the existing real-time path planning solutions of the plurality of terminals to update and improve a dynamic road section database inside the cloud platform (101); and when the cloud platform receives a certain path planning request with specific requirements proposed by the mobile terminals, according to data of the updated and improved dynamic road section database inside the cloud platform, figuring out, by the cloud platform, corresponding path planning, and then wirelessly sending same to the mobile terminals (102). The method has the advantages of using mobile terminals on a large scale to collect track information used as dynamic traffic information and conducting precise navigation, accurate prediction, reasonable avoidance of crowded roads, and accurate avoidance of roads closed to passage.
Description
本申请要求2013-10-09在中国提交的专利号:201310466623.3的优先权。This application claims priority from Japanese Patent Application No. 201310466623.3, filed on Jan.
本发明属于导航领域,尤其涉及一种动态轨迹导航方法及云平台。The invention belongs to the field of navigation, and in particular relates to a dynamic track navigation method and a cloud platform.
伴随着移动互联网、云计算、ITS智能交通系统、车联网应用技术的发展和智慧城市建设的日益深入,及我国第二代北斗卫星导航系统BD2的发展成熟,动态导航技术的深入研究显得愈来愈重要也愈来愈迫切。With the development of mobile Internet, cloud computing, ITS intelligent transportation system, vehicle networking application technology and the construction of smart city, and the development of China's second generation Beidou satellite navigation system BD2, the in-depth study of dynamic navigation technology is becoming more and more The more important it is, the more urgent it is.
路段、结点、形值点的定义及静态交通限制信息。在实际情况中,为了避免过多地考虑道路间的拓扑关系,一般抽取道路网络图中道路交叉路口作为分析的对象,并定义这个交叉路口为结点之一,结点还可包括道路的尽头、或者道路属性改变的地方;同时对道路以结点进行分割,并定义两个最近结点之间的一段道路为路段。这样,整个道路网络图将由结点和路段组成,交叉路口点为网络的结点,路段为网络的弧,名称相同的相互连接的若干条路段则构成了一条道路。路段则可以用折线来描述,在折线转折处的顶点称为道路形值点。形值点存在于路段上,两相邻形值点之间的部分称为此路段的子路段。静态的交通限制信息指的是在一个实际交通网络中,较长时间内不会发生变化的固定的交通限制:单行线,禁止转弯,禁止掉头。处理这种信息,首先需要建立道路拓扑关系的模型以及得到对静态交通限制信息的表示方法,使得这些信息可以融合到交通路网模型中并且能够被系统方便的识别和存储。Road segments, nodes, definitions of shape points and static traffic restrictions. In the actual situation, in order to avoid excessive consideration of the topological relationship between roads, the road intersection in the road network map is generally extracted as the object of analysis, and the intersection is defined as one of the nodes, and the node may also include the end of the road. Or where the road property changes; at the same time, the road is segmented by nodes, and a section of the road between the two nearest nodes is defined as a road segment. In this way, the entire road network map will be composed of nodes and road segments. The intersection points are the nodes of the network, the road segments are the arcs of the network, and several interconnected road segments with the same name form a road. The road segment can be described by a broken line, and the apex at the turning point of the polyline is called a road shape value point. The shape value point exists on the road segment, and the portion between the two adjacent shape value points is called the sub-section of the road segment. Static traffic restriction information refers to fixed traffic restrictions that do not change over a long period of time in an actual transportation network: single-line, no turning, no U-turn. To process this information, it is first necessary to establish a model of the road topology relationship and to obtain a representation of the static traffic restriction information so that the information can be integrated into the traffic network model and can be easily identified and stored by the system.
实时交通信息的采集。以前,交通信息的取得大多依赖于道路上的交通流检测设备,如环形感应线圈、雷达、视频照片、牌照识别、红外传感器和浮动车辆(FC)等。近一、二年才开始用移动终端来采集路况信息,比如现在,主要是在用大量的出租车的行驶轨迹来充实实时交通信息,特别是作为实时路况的主要信息来源。Real-time traffic information collection. Previously, the acquisition of traffic information relied mostly on traffic flow detection equipment on the road, such as ring induction coils, radar, video photos, license plate recognition, infrared sensors and floating vehicles (FC). In the past one or two years, mobile terminals have been used to collect road condition information. For example, nowadays, a large number of taxi trajectories are used to enrich real-time traffic information, especially as a main source of information for real-time road conditions.
道路交通状况的预测。由于交通路况信息是变化的,如果出行者按他出发前的交通信息选定路线,也许当他到达某个交叉口时,本应顺畅的道路已经变得拥挤不堪。所以实时预测道路未来某段时间内的交通状况,对精准导航至关重要。目前,对这个方面的研究成效并不显著。Forecast of road traffic conditions. Since the traffic condition information is changing, if the traveler selects the route according to the traffic information before his departure, perhaps when he arrives at an intersection, the road that should have been smooth has become overcrowded. Therefore, real-time prediction of the traffic conditions of the road in a certain period of time is crucial for precise navigation. At present, the research on this aspect is not effective.
在实现现有技术的技术方案中,发现存在如下问题:In implementing the technical solutions of the prior art, the following problems are found:
由于以前无线通信技术的限制,移动互联网终端的匮乏及云平台的缺乏,从技术上无法实现大规模的使用移动终端来采集轨迹信息用作动态的交通信息,导致至今为止还没有一个成熟有效的动态导航方法。而最为接近本技术的国外的有美国的INRIX,国内的有高德、四图维新,它们能根据实时路况信息计算的所谓最优路径,但也只是依赖原有地图上的道路数据和红绿黄主干路上的定性的拥堵信息来进行运算的,给出的路径规划往往还是很不合理;而作为动态导航技术的一个重要方面——未来道路交通状况的预测,迄今为止,也没有一个比较理想的模型和方法。
Due to the limitations of previous wireless communication technologies, the lack of mobile Internet terminals and the lack of cloud platforms, it is technically impossible to achieve large-scale use of mobile terminals to collect track information for dynamic traffic information, resulting in a mature and effective one. Dynamic navigation method. The foreign countries closest to this technology are the US INRIX, the domestic high-tech, four-dimensional new, they can calculate the so-called optimal path based on real-time road condition information, but only rely on the road data and red and green on the original map. The qualitative congestion information on the yellow trunk road is used for calculation, and the path planning given is often very unreasonable. As an important aspect of dynamic navigation technology - the prediction of future road traffic conditions, so far, there is no ideal. Models and methods.
发明内容Summary of the invention
本发明实施例的目的在于提供一种云平台中心控制式的动态轨迹导航方法,旨在解决现有技术无法将轨迹信息直接运用到路径规划化的定量计算中、导致路径规划不合理、反应路况变化不敏感的问题;同时提供一种全新的预测拥堵路况的方法,并可根据预测结果计算出一种行驶时间最短的路径规划方案;而这种预测方法,是根据相关移动终端上传的正在使用的终端已有实时路径规划方案而得出的,因而当相关的移动终端数量足够多时,该预测方法是比较可靠的。The object of the embodiments of the present invention is to provide a cloud platform central control type dynamic trajectory navigation method, which aims to solve the problem that the prior art cannot directly apply the trajectory information to the quantitative calculation of path planning, resulting in unreasonable path planning and reaction road conditions. The problem of change insensitivity; at the same time, it provides a new method for predicting congestion road conditions, and can calculate a path planning scheme with the shortest travel time based on the predicted result; and this prediction method is based on the upload of the relevant mobile terminal. The terminal has been derived from a real-time path planning scheme, so the prediction method is relatively reliable when the number of related mobile terminals is sufficient.
一方面,提供一种动态的导航路径规划方法,所述方法包括:In one aspect, a dynamic navigation path planning method is provided, the method comprising:
云平台实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;The cloud platform receives multiple track information uploaded by multiple mobile terminals in real time or multiple real-time path planning schemes of multiple terminals, and then uses the multiple track information or multiple terminals to have a real-time path planning solution to update and improve the cloud platform. Internal dynamic road segment database;
当云平台接收到移动终端提出的某一有特定要求的路径规划请求时,云平台根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出和某一有特定要求的路径规划请求相应的路径规划,然后将所述相应的路径规划以无线方式发送给移动终端;When the cloud platform receives a specific path planning request from the mobile terminal, the cloud platform calculates a path plan with a specific requirement according to the dynamic road segment database data in the updated and improved cloud platform. Requesting a corresponding path plan, and then transmitting the corresponding path plan to the mobile terminal in a wireless manner;
所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片图像及获取时间,轨迹所属移动终端的代码;所述轨迹的数量,是指在所统计的时间范围和空间范围内,将每一个移动终端上传的连续的二维或三维的空间位置坐标点按由先到后的时间顺序连接形成一条轨迹,然后累加这些所述轨迹条数,所得出的数量;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the trajectory belongs; the number of trajectories refers to consecutive two-dimensional or three-dimensional spatial position coordinate points uploaded by each mobile terminal within the statistical time range and spatial range Forming a trajectory in a chronological order from first to last, and then accumulating the number of the trajectories to obtain a quantity;
所述终端已有实时路径规划方案是指已经存在于所述移动终端内部的、正在使用的、从所述移动终端本次上传开始时的所在地到目的地的一个行驶方案,它能告诉云平台所述移动终端从哪里开始、走哪条路、将要到哪里去;主要的作用是用来预测未来道路的拥堵状况的,它是随着移动终端的不断移动而不断变化的;实际上,它也类似于一个轨迹----一个未来可能形成的轨迹;它不是指云平台给移动终端做出的并将要发送给移动终端的路径规划。The real-time path planning scheme of the terminal refers to a driving plan that is already existing in the mobile terminal and is in use, from the location to the destination when the mobile terminal starts this uploading, which can tell the cloud platform Where does the mobile terminal start, which way to go, and where it will go; the main role is to predict the congestion of the road in the future, which is constantly changing as the mobile terminal continues to move; in fact, it It is also similar to a trajectory--a trajectory that may be formed in the future; it does not refer to the path plan that the cloud platform makes to the mobile terminal and will send to the mobile terminal.
如果一编号为1号的车辆从一路段VW的结点V驶向另一结点W,设t1v为1号车辆到达结点V的时刻,T1vw(t1v)为1号车辆到达结点W所耗费的时间,即耗时,则n辆车辆的在某个时间区域T内的耗时:T1vw(t1v),T2vw(t2v),……Tnvw(tnv)的加权平均数,构成了平均耗时,这个平均耗时则定义Tpnvw,也称之为路段vw在T时间区域从V到W的动态阻抗。如果这个时间区域T是同现有轨迹信息相对应的已经过去的时间,则为即时动态阻抗;如果这个时间区域T是某一指定的未来的一个时间区域,那么用这个未来时间区域T和终端已有实时路径规划方案、云平台历史数据计算出来的动态阻抗,则称为预测动态阻抗。If a vehicle numbered 1 is driven from the node V of one road segment VW to another node W, let t1v be the time when the vehicle No. 1 reaches the node V, and T1vw(t1v) is the vehicle No. 1 arrive at the node W. The time spent, ie time consuming, the time spent in a certain time zone T of n vehicles: T1vw (t1v), T2vw (t2v), ... Tnvw (tnv) weighted average, constitutes the average time consuming This average time-consuming defines Tpnvw, also known as the dynamic impedance of the segment vw from V to W in the T-time region. If the time zone T is the elapsed time corresponding to the existing trajectory information, it is the instantaneous dynamic impedance; if the time zone T is a specified future time zone, then the future time zone T and the terminal are used. The dynamic impedance calculated by the real-time path planning scheme and the historical data of the cloud platform is called the predicted dynamic impedance.
在一个云平台内部,用多个移动终端的实时上传的轨迹信息和终端已有实时路径规划方案,生成和更新新的路段、生成和更新模拟交通限制信息、生成和更新即时动态阻抗、生成和更新预测动态阻抗,这样形成的一个动态的有关路段的数据库称为动态路段数据库。Within a cloud platform, real-time uploaded trajectory information of multiple mobile terminals and the terminal's existing real-time path planning scheme, generate and update new road segments, generate and update simulated traffic restriction information, generate and update instantaneous dynamic impedance, generate and Updating the predicted dynamic impedance, such a dynamic database of related segments is called a dynamic segment database.
所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据、生成和更新所有路段的即时动态阻抗、生成和
更新所有路段的模拟交通限制信息,另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating road segment data on an unknown road, generating and updating real-time dynamic impedance of all road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. , generation and
Updating simulated traffic restriction information of all road segments, and generating and updating predicted dynamic impedances of all road segments according to the existing real-time path planning scheme and trajectory historical data of the plurality of terminals;
所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指构成轨迹各点的经纬度的获取时间所组成的一个和各点对应的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory; The acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
第二方面,提供一种云平台,所述云平台包括多个智能设备,所述智能设备包括:处理器、存储器、通信接口和总线;In a second aspect, a cloud platform is provided, where the cloud platform includes multiple smart devices, and the smart device includes: a processor, a memory, a communication interface, and a bus;
所述通信接口实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,处理器然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;当通信接口接收到移动终端提出的某一有特定要求的路径规划请求时,处理器根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出和某一有特定要求的路径规划请求相应的路径规划,然后将所述相应的路径规划以无线方式发送给移动终端;The communication interface wirelessly receives multiple track information uploaded by multiple mobile terminals or multiple real-time path planning schemes of multiple terminals in real time, and the processor then uses the multiple track information or multiple terminals to have an existing real-time path planning scheme to update And perfecting the dynamic link database inside the cloud platform; when the communication interface receives a path planning request with specific requirements proposed by the mobile terminal, the processor calculates the dynamic road segment database data according to the updated and improved cloud platform. And corresponding a path planning request with a specific path planning request, and then transmitting the corresponding path planning to the mobile terminal in a wireless manner;
所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片图像及获取时间,轨迹所属移动终端的代码;所述轨迹的数量,是指在所统计的时间范围和空间范围内,将每一个移动终端上传的连续的二维或三维的空间位置坐标点按由先到后的时间顺序连接形成一条轨迹,然后累加这些所述轨迹条数,所得出的数量;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the trajectory belongs; the number of trajectories refers to consecutive two-dimensional or three-dimensional spatial position coordinate points uploaded by each mobile terminal within the statistical time range and spatial range Forming a trajectory in a chronological order from first to last, and then accumulating the number of the trajectories to obtain a quantity;
所述终端已有实时路径规划方案是指移动终端正在使用的、从本次上传开始时的所在的地到目的地的一个路径规划方案;The real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal to go from the place where the uploading starts to the destination;
所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据、所有路段的即时动态阻抗和所有路段的模拟交通限制信息,另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating the traffic restriction information, and generating and updating the predicted dynamic impedance of all the road segments according to the existing real-time path planning scheme and the trajectory historical data of the plurality of terminals;
所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指构成轨迹各点的经纬度的获取时间所组成的一个和各点对应的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory; The acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
在本发明实施例中,本发明提供的技术方案具有实现大规模的使用移动终端来采集轨迹信息用作动态的交通信息并进行精准合理导航的优点。In the embodiment of the present invention, the technical solution provided by the present invention has the advantages of realizing large-scale use of the mobile terminal to collect track information for dynamic traffic information and accurately and reasonably navigate.
图1是本发明具体实施方式提供的一种动态的导航路径规划方法的流程图;1 is a flowchart of a dynamic navigation path planning method according to an embodiment of the present invention;
图2是本发明具体实施方式提供的云平台的结构示意图。2 is a schematic structural diagram of a cloud platform according to an embodiment of the present invention.
为了使本发明的目的、技术方案及优点更加清楚明白,以下结合附图及实施例,对本发明进行
进一步详细说明。应当理解,此处所描述的具体实施例仅仅用以解释本发明,并不用于限定本发明。In order to make the objects, technical solutions and advantages of the present invention more comprehensible, the present invention will be described below with reference to the accompanying drawings and embodiments.
Further details. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
本发明最显著的创造性之一是将导航系统内的固态路段数据库改变为随轨迹信息变化而变化的动态路段数据库。One of the most significant inventive aspects of the present invention is to change the solid-state road segment database within the navigation system to a dynamic road segment database that changes as the trajectory information changes.
本发明最显著的创造性之一是将多个移动终端的终端已有实时路径规划方案实时上传至云平台中心,并根据所述的终端已有实时路径规划方案和云平台中的历史数据计算出预测动态阻抗,用作预测未来道路拥堵状况和计算路径规划。One of the most significant innovations of the present invention is that a real-time path planning scheme of a terminal of a plurality of mobile terminals is uploaded to the cloud platform center in real time, and is calculated according to the existing real-time path planning scheme of the terminal and historical data in the cloud platform. Predict dynamic impedance, used to predict future road congestion conditions and calculate path planning.
本发明可以说是一个云计算、大数据、移动互联网、车联网、北斗导航时代的产物。因为本技术中所述的上传的多个轨迹信息的数量是指所谓的海量的、大数据的数量级,也就是说所述的多个轨迹信息是指海量的即数以万计的或亿以上数量级的、连续不断的稠密轨迹信息流,只有在这种情况下,用轨迹数量来进行相关计算才会有好的效果。The invention can be said to be a product of cloud computing, big data, mobile internet, car networking, and Beidou navigation era. Because the number of uploaded pieces of trajectory information described in the present technology refers to the so-called massive, large data order of magnitude, that is to say, the plurality of trajectory information refers to a massive amount of tens of thousands or more Orderly, continuous, dense trajectory information flow, only in this case, the correlation calculation with the number of trajectories will have a good effect.
本发明最显著的创造性之一是将路径规划的主体由原来的移动终端转移到一个控制中心——云平台系统内部,并且将这个云平台系统内的通常为固态的路段数据库改变为随轨迹信息变化而变化的动态的路段数据库;同时本技术运用了云计算技术,采用了海量的轨迹信息,并根据统计学的原理计算所谓的大数据,用轨迹的数量和轨迹获取时间作为重要参量,来实时的、动态的改变云平台内部的动态路段数据库。One of the most significant inventive aspects of the present invention is to transfer the main body of the path planning from the original mobile terminal to a control center, inside the cloud platform system, and change the usually solid state road segment database within the cloud platform system to the track information. Dynamic and dynamic segment database with changes; at the same time, this technology uses cloud computing technology, uses massive trajectory information, and calculates so-called big data according to statistical principles, using the number of trajectories and trajectory acquisition time as important parameters. Real-time, dynamic change of dynamic road segment database inside the cloud platform.
本发明实施例是这样实现的,在包括GPS或BD2定位系统下,一个云计算平台实时无线接收所有系统内客户装载在车辆上的移动终端——即具有通信功能的定位装置(如出租车定位监控设备)或导航装置(如智能手机)发送的轨迹信息,然后进行处理和运算,动态地更新云平台内部的路段数据库,生成即时动态阻抗权值和预测动态阻抗权值,或生成新的路段、模拟生成新的交通限制信息,在接收到移动终端提出的路径规划请求时,云平台根据这些更新了的动态路段数据库数据计算出一个路径规划,再发送给移动终端。具体实现的主要技术原理为:将接收到的轨迹信息,舍弃异常点,并进行卡尔曼滤波处理,去除噪声,然后对GIS中的原有的路段数据进行投影,如成功则用轨迹信息中包含的时间数据改变该路段的即时动态阻抗权值;如不成功则另外生成临时路段存储到路段数据库中并自行生成即时动态阻抗权值。当客户提出最短时间路径规划时,先按照常规的最短路径算法(如A*算法)求出n条最短路径,n条最短路径里可包括新生成的路段,然后再在这n条路径规划中,根据所包含的的路段的即时动态阻抗权值的叠加,选出总体耗时最短的路径规划,即为最短时间路径规划。同时,还可根据多个移动终端上传的实时路径规划,计算出未来某时某路段的预测动态阻抗,并将其运用到某些路径规划的计算中。The embodiment of the present invention is implemented. Under the GPS or BD2 positioning system, a cloud computing platform wirelessly receives all mobile terminals loaded by the customer on the vehicle in real time, that is, a positioning device with communication function (such as taxi positioning). Tracking information sent by the monitoring device or navigation device (such as a smart phone), then processing and computing, dynamically updating the road segment database inside the cloud platform, generating real-time dynamic impedance weights and predicting dynamic impedance weights, or generating new road segments The new traffic restriction information is generated by the simulation. When receiving the path planning request from the mobile terminal, the cloud platform calculates a path plan according to the updated dynamic link database data, and then sends the path plan to the mobile terminal. The main technical principle of the specific implementation is as follows: the received trajectory information is discarded, and the Kalman filter processing is performed to remove the noise, and then the original road segment data in the GIS is projected. If successful, the trajectory information is included in the trajectory information. The time data changes the instantaneous dynamic impedance weight of the road segment; if it is unsuccessful, the temporary road segment is additionally generated and stored in the road segment database and generates an instantaneous dynamic impedance weight. When the customer proposes the shortest time path planning, the shortest path is first obtained according to the conventional shortest path algorithm (such as A * algorithm), and the newly generated road segments can be included in the n shortest paths, and then in the n path planning. According to the superposition of the instantaneous dynamic impedance weights of the included road segments, the path planning with the shortest overall time is selected, that is, the shortest time path planning. At the same time, according to the real-time path planning uploaded by multiple mobile terminals, the predicted dynamic impedance of a certain road segment at a certain time in the future can be calculated and applied to the calculation of some path planning.
所述云平台即为云计算平台,是指一种具有超强的存储和计算能力的、基于互联网的、其存储和计算资源海量的、可按需动态部署、动态优化、动态收回的,以虚拟化方式共享资源的一系列计算机群和数据平台。因为本技术中的所述多个移动终端,其实是指海量的即数以万计的或亿以上数量级的移动终端,在这里一个移动终端上传的轨迹信息定义为一个轨迹信息,而多个轨迹信息,则是指海量的即数以万计的或亿以上数量级的、连续不断的稠密轨迹信息流,只有使用这种具有超强计算能力的云平台,才有可能完成这种繁杂的计算任务。The cloud platform is a cloud computing platform, which refers to a network-based, massive storage and computing resource with dynamic storage and computing capabilities, dynamically deployable on demand, dynamically optimized, and dynamically reclaimed. A series of computer clusters and data platforms that share resources in a virtualized manner. Because the plurality of mobile terminals in the present technology actually refers to a mass of tens of thousands or more than 100 million mobile terminals, where the track information uploaded by one mobile terminal is defined as one track information, and multiple tracks Information refers to massive, tens of thousands or more orders of magnitude and continuous dense trajectory information flow. It is only possible to complete such complicated computing tasks by using such a cloud platform with superior computing power. .
本发明实施例与现有技术相比,有益效果在于:本发明采用的数据是全面的、连续的、繁杂的、
海量的轨迹信息,因样本量大所以可信度高;其收集存储及计算、以及路径规划是在一个云平台的内部进行的,计算量大、速度快;并且具有动态的、能利用地图上没有的新的道路实施导航的、能利用轨迹信息更新交通限制信息的、能动态的定量的计算总体路径规划耗时的、能实时反应路况变化的优点;另外还可根据众多相关的多个移动终端正在使用的终端已有实时路径规划方案,预测未来某时某个路段的拥堵状况。Compared with the prior art, the embodiment of the present invention has the beneficial effects that the data used in the present invention is comprehensive, continuous, and complicated.
Massive trajectory information, because of the large sample size, so the credibility is high; its collection, storage and calculation, and path planning are carried out inside a cloud platform, with large amount of calculation and fast speed; and it has dynamic and can be used on the map. There is no new road to implement navigation, can use the trajectory information to update the traffic restriction information, can dynamically calculate the overall path planning time-consuming, real-time reaction to the change of road conditions; in addition, according to many related multiple movements The terminal that the terminal is using has a real-time path planning scheme to predict the congestion status of a certain road segment at a certain time in the future.
需要说明的是,上述包括生成新的路段的更新动态路段数据库的方法,应以不违反相关国家有关测绘方面的法规法律为前提。It should be noted that the above method for updating the dynamic road segment database including the generation of new road segments should be based on the premise of not complying with the laws and regulations concerning surveying and mapping in the relevant countries.
本发明具体实施方式提供一种动态的导航路径规划方法,该方法如图1所示,包括:The specific embodiment of the present invention provides a dynamic navigation path planning method, which is shown in FIG. 1 and includes:
101、云平台实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;101. The cloud platform receives multiple track information uploaded by multiple mobile terminals or multiple real-time path planning schemes of multiple terminals in real time, and then uses the multiple track information or multiple terminals to have an existing real-time path planning solution, which is updated and improved. Dynamic road segment database inside the cloud platform;
102、当云平台接收到移动终端提出的某一有特定要求的路径规划请求时,云平台根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出和某一有特定要求的路径规划请求相应的路径规划,然后将所述相应的路径规划以无线方式发送给移动终端;102. When the cloud platform receives a path planning request with a specific requirement by the mobile terminal, the cloud platform calculates and selects a specific requirement according to the dynamic road segment database data in the updated and improved cloud platform. The path plan requests a corresponding path plan, and then the corresponding path plan is sent to the mobile terminal in a wireless manner;
上述终端已有实时路径规划方案是指移动终端内部已有的且正在使用的、从所述移动终端本次上传开始时的所在地到目的地的一个路径规划方案;The real-time path planning scheme of the foregoing terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;
所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片图像及获取时间,轨迹所属移动终端的代码;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the track belongs;
所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据、所有路段的即时动态阻抗和所有路段的模拟交通限制信息,另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating the traffic restriction information, and generating and updating the predicted dynamic impedance of all the road segments according to the existing real-time path planning scheme and the trajectory historical data of the plurality of terminals;
所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指构成轨迹各点的经纬度的获取时间所组成的一个和各点对应的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory; The acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
所述轨迹的数量,是指在所统计的时间范围和空间范围内,将每一个移动终端上传的连续的二维或三维的空间位置坐标点按由先到后的时间顺序连接形成一条轨迹,然后累加这些所述轨迹条数,所得出的数量;所述终端已有实时路径规划方案是指移动终端正在使用的、从本次上传开始时的所在的地到目的地的一个路径规划方案。The number of the trajectories refers to a continuous two-dimensional or three-dimensional spatial position coordinate point uploaded by each mobile terminal in a chronological time range and a spatial range, forming a trajectory in a chronological order from first to last. Then, the number of the track segments is accumulated, and the obtained number is obtained. The real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal to go from the place where the upload starts to the destination.
可选的,上述生成和更新未知道路上的路段数据的方法包括:当多个移动终端在未知道路上行驶,其上传的轨迹信息不能匹配到云平台的动态路段数据库中原有的路段数据上时,云平台将这些所述的不能匹配到云平台的动态路段数据库中原有的路段上的轨迹信息,舍弃异常点,去除噪声,并按一定方法整理合并成一条模拟道路,并暂存到动态路段数据库中,同时计算模拟道路中的轨迹数量;当在某一时间区间内,合并在这条模拟道路上的轨迹数量达到某一设定阈值时,云平台将这
条模拟道路转变成一条或几条新的临时或永久的新生成路段数据,存储到动态路段数据库中,云平台还根据实时上传的新的轨迹信息对所述的新生成路段数据不断更新;需要说明的是,所述去除噪声,可采用卡尔曼滤波算法实现。Optionally, the foregoing method for generating and updating road segment data on an unknown road includes: when a plurality of mobile terminals are traveling on an unknown road, and the uploaded track information cannot be matched to the original road segment data in the dynamic road segment database of the cloud platform. The cloud platform discards the trajectory information on the original road segment in the dynamic road segment database that cannot be matched to the cloud platform, discards the abnormal point, removes the noise, and merges and merges into a simulated road according to a certain method, and temporarily stores it into the dynamic road segment. In the database, the number of trajectories in the simulated road is simultaneously calculated; when the number of trajectories merged on this simulated road reaches a certain threshold within a certain time interval, the cloud platform will
The simulated road is transformed into one or several new temporary or permanent newly generated road segment data, which is stored in the dynamic road segment database, and the cloud platform also continuously updates the newly generated road segment data according to the newly uploaded new track information; It is noted that the noise removal can be implemented by a Kalman filter algorithm.
上述更新完善该云平台内的动态路段数据库具体可以采用下述方式中的任意一种或组合:The foregoing update and improvement of the dynamic link database in the cloud platform may specifically adopt any one or combination of the following manners:
方式A、云平台根据多个移动终端实时上传的轨迹的数量及轨迹的获取时间,计算出某一路段上某一时间区域的轨迹的平均耗时,并把所述的平均耗时作为一个即时动态阻抗存储在一个数据库中,所述某一路段是原有道路上的路段或是未知道路上新生成的路段;Method A: The cloud platform calculates the average time consuming of the trajectory of a certain time zone on a certain road segment according to the number of trajectories uploaded by the mobile terminal in real time and the acquisition time of the trajectory, and uses the average time consuming as an instant The dynamic impedance is stored in a database, and the certain road segment is a road segment on the original road or a newly generated road segment on the unknown road;
当采用方式A时,当移动终端提出的某一特定要求的路径规划请求为:最短时间的路径规划请求时,所述云平台根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出某一有特定要求的路径规划请求相应的路径规划具体包括:云平台用包含了这些即时动态阻抗的数据库数据,计算总体耗时最短的路径规划。When the mode A is adopted, when the path planning request of the specific requirement proposed by the mobile terminal is: the shortest time path planning request, the cloud platform is based on the dynamic road segment database data inside the updated and improved cloud platform. Calculating a path planning request with specific requirements The corresponding path planning specifically includes: the cloud platform uses the database data including these instantaneous dynamic impedances to calculate the path plan with the shortest overall time consumption.
方式B、云平台将包括在原有道路和未知道路上行驶的众多移动终端上传的轨迹的获取时间存储到云平台的动态数据库中,并将所述轨迹的获取时间与所述轨迹的获取时间对应路段相关联;当移动终端设定一时间区域,并提出请求:当一些存储在所述动态数据库中的轨迹获取时间落入这个所述时间区域时,找出这些获取时间所对应的轨迹,再找出所述对应的轨迹所在的路段,然后用这些路段拼接出一个路径规划,云平台则根据移动终端的请求用符合条件的路段,计算出路径规划。In the mode B, the cloud platform stores the acquisition time of the trajectory uploaded by the plurality of mobile terminals that are driven on the original road and the unknown road into a dynamic database of the cloud platform, and the acquisition time of the trajectory corresponds to the acquisition time of the trajectory. The road segment is associated; when the mobile terminal sets a time zone, and makes a request: when some track acquisition time stored in the dynamic database falls into the time zone, find the trajectory corresponding to the acquisition time, and then Find the road segments where the corresponding trajectories are located, and then use these road segments to splicing out a path plan, and the cloud platform calculates the path plan according to the requirements of the mobile terminal using the qualified road segments.
方式C、云平台将众多终端上传的某路段上的轨迹的数量,存储到云平台的数据库中,并与对应路段相关联;当移动终端设定一个数量阈值,并提出当一些路段上的轨迹数量落入这个数量阈值时,找出这些路段,然后用这些路段拼接出一个路径规划的请求时,云平台则根据移动终端的请求用符合条件的路段,拼接出路径规划。Method C: The cloud platform stores the number of tracks on a certain road segment uploaded by a plurality of terminals in a database of the cloud platform, and is associated with the corresponding road segment; when the mobile terminal sets a threshold number, and proposes a track on some road segments When the quantity falls into the threshold of the quantity, the road sections are found out, and then the request of the path planning is spliced by the road sections, and the cloud platform splices out the path plan according to the request of the mobile terminal according to the conditional road section.
还可以将方式B和方式C结合使用,即选取某一段时间之内、拥有某一定轨迹数量的路段,来拼接路径规划。这样做的意义之一是:可避开因为维修或事故等原因导致封闭禁行的一些路段,因为在这种情况下,这些路段的在这个封闭禁行的时间区域里的车辆轨迹数量显然趋向于零。而现有的技术,对这种常见的情况却是不能识别的。It is also possible to combine the mode B and the mode C, that is, select a road segment having a certain number of tracks within a certain period of time to splicing the path planning. One of the significance of this is that it can avoid some road sections that are closed due to maintenance or accidents, because in this case, the number of vehicle tracks in these closed time zones is obviously trending. At zero. The existing technology is not identifiable for this common situation.
可选的,上述方法在101和102之间还包括:Optionally, the foregoing method further includes between 101 and 102:
通过检验在未知道路和原有道路某一时间区域、某一指定路段上的轨迹数量,模拟生成禁止允许转弯、转弯交通限制信息、允许掉头、禁止掉头交通限制信息或单行线交通限制信息。By checking the number of trajectories on a certain time zone and a certain road section of the unknown road and the original road, the simulation generates a prohibition of allowing turning, turning traffic restriction information, allowing U-turn, prohibiting U-turn traffic restriction information or one-way traffic restriction information.
可选的,模拟生成允许转弯或禁止转弯交通限制信息包括:云平台检验两个相交的路段是否共同拥有连续的同一移动终端形成的某行驶方向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的数量、或者同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照轨迹行驶方向可以转弯的交通限制信息,存储到一个特殊的数据库中,反之,当这个计算结果小于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照轨迹行驶方向禁止转弯的交通限制信息,存储到一个特殊的数据库中。Optionally, the simulation generation allows the turning or prohibiting the turning traffic restriction information includes: the cloud platform checks whether the two intersecting road sections have a continuous trajectory of a certain traveling direction formed by the same mobile terminal, and calculates in a set time zone. The number of such trajectories or the relative number of the trajectories compared with the relevant trajectories. When the calculation result is greater than a predetermined value, the simulated generation of the intersections between the two road segments according to the trajectory direction The traffic restriction information that can be turned is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulated generation of the intersection between the two links is prohibited according to the direction of the trajectory. Turn traffic restrictions are stored in a special database.
可选的,上述模拟生成允许掉头或禁止掉头交通限制信息包括:云平台检验某一个路段是否存在以某形值点为转折点的同一移动终端连续形成的正向和反向的轨迹,并计算在一个设定的时间区
域内这类所述轨迹的数量,或者,同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这个路段之间的可以在这个转折点按照所述轨迹转折方向掉头的交通限制信息,存储到一个特殊的数据库中,反之,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段之间的禁止在这个转折点按照所述轨迹转折方向掉头的交通限制信息,存储到一个特殊的数据库中。Optionally, the foregoing simulation generation allows the U-turn or the U-turn traffic restriction information to include: the cloud platform checks whether a certain road segment has a forward and reverse trajectory continuously formed by the same mobile terminal with a shape point as a turning point, and calculates a set time zone
The number of such trajectories in the domain, or the relative number of the trajectories compared with the relevant trajectories. When the calculation result is greater than a predetermined value, the simulation between the generated segments can be turned according to the trajectory at the turning point. The traffic restriction information of the direction U-turn is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulation generates a prohibition between the road segments at the turning point according to the direction of the trajectory turning. Traffic restriction information is stored in a special database.
上述模拟生成单行线交通限制信息包括:云平台检验某个的路段某个方向的移动终端形成的轨迹数量,并计算在一个设定的时间区域内这类所述轨迹的数量,或者,同相反方向的或其他相关的轨迹相比较的相对数量,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段在这个所述方向的禁止通行的交通限制信息,存储到一个特殊的数据库中。The above-mentioned simulation generates single-line traffic restriction information, including: the cloud platform checks the number of tracks formed by the mobile terminal in a certain direction of a certain road segment, and calculates the number of such tracks in a set time region, or the same direction The relative number of comparisons of other or related trajectories. When the result of the calculation is less than a predetermined value, the traffic restriction information of the prohibited passage in the direction of the road segment is simulated and stored in a special database. .
可选的,上述云平台根据所述更新和完善所述云平台内部的动态路段数据库的数据计算出相应的路径规划包括:Optionally, the foregoing cloud platform calculates, according to the updated and improved data of the dynamic link database in the cloud platform, a corresponding path plan, including:
云平台先采用静态的常规的最短路径计算方法计算出n条总体距离最短的路径规划方案,再在n条最短路径规划方案中根据所在路段上的即时动态阻抗选出总体耗时最短的一条路径规划,所述路段包括:原有道路和未知道路上的路段。The cloud platform first uses the static conventional shortest path calculation method to calculate the path planning scheme with the shortest overall distance, and then selects the shortest path with the shortest time according to the instantaneous dynamic impedance on the road segment in the n shortest path planning scheme. Planning, the road section includes: original roads and road sections on unknown roads.
上述静态的常规的最短路径计算方法,是指一种称之为:A*启发式搜索算法;这种算法是用来根据所述更新和完善了的云平台内部的动态路段数据库数据计算出n条总体距离最短的路径规划方案的;所述A*启发式搜索算法,包括下限为0的A*启发式搜索算法的一种特例:dijkstra算法。The above static conventional shortest path calculation method refers to a method called: A * heuristic search algorithm; the algorithm is used to calculate the dynamic road segment database data based on the updated and improved cloud platform. The A * heuristic search algorithm includes a special case of the A * heuristic search algorithm with a lower bound of 0: the dijkstra algorithm.
可选的,上述利用这些轨迹信息更新和完善在这个云平台内部的路段数据库,是指将根据轨迹信息模拟生成的新的路段数据同原有路段数据一起存储在一个以邻接表方式表达的一个数据库中。Optionally, the foregoing updating and perfecting the road segment database in the cloud platform by using the trajectory information means that the new road segment data generated by the trajectory information simulation is stored together with the original road segment data in a neighboring table manner. In the database.
可选的,上述云平台根据这些更新和完善了的路段数据库数据,计算出相应的路径规划具体包括:Optionally, the cloud platform calculates the corresponding path plan according to the updated and improved road segment database data, and specifically includes:
将轨迹信息中的高程和二维或三维运动方向信息、同所在路段相关联并加权平均后同视频、照片数据一起存储在数据库中,用以区分近似路段;当云平台用包括高架桥上下高度不同但水平面位置相近或相同的、或其它高度相同但水平位置接近的一些所述近似路段进行路径规划时,云平台检验所述近似路段结点的经纬度坐标,当两个路段对应结点的经度坐标值之差和纬度坐标值之差的绝对值同时小于一个设定的值时,则自动读取行驶在所述两个路段上面的移动终端的可以包括平均高程、行驶方向、视频、照片的轨迹信息;还可以同时计算所述两个路段与各自的前后相邻路段的衔接关系,并进行标记和提示,一起存储在动态路段数据库中,云平台根据存储在动态路段数据库中的所述的轨迹信息和衔接关系,计算路径规划;然后将所述的移动终端的可以包括平均高程、行驶方向、视频、照片的轨迹信息和所述衔接关系连同标记和提示,同计算出的路径规划方案一起,发送给移动终端;所述计算衔接关系,是指累加在某个路段上的每一个移动终端在直行或转弯、跨越结点行驶到相邻的路段时形成的连续轨迹的数量,当这个数量在一设定的时间区域内落入一个设定的阈值时,或当在一设定的时间区域内,用所述的连续轨迹的数量同相关轨迹数量相比,其比值落入一个设定的阈值时,则确认为这两个路段在这个轨迹运行的方向上有衔接关系。The elevation and 2D or 3D motion direction information in the trajectory information are associated with the road segment and weighted and averaged, and then stored in the database together with the video and photo data to distinguish the approximate road segment; when the cloud platform includes the viaduct, the height is different. However, when some similar sections of the horizontal plane are similar or identical, or other similar heights but the horizontal positions are close to each other, the cloud platform checks the latitude and longitude coordinates of the approximate road segment nodes, and the longitude coordinates of the corresponding nodes of the two road sections. When the absolute value of the difference between the value difference and the latitude coordinate value is less than a set value at the same time, automatically reading the trajectory of the mobile terminal traveling on the two road segments may include the average elevation, the traveling direction, the video, and the photo. Information; it is also possible to simultaneously calculate the connection relationship between the two road segments and the respective adjacent road segments, and mark and prompt, and store them together in the dynamic road segment database, and the cloud platform is based on the trajectory stored in the dynamic road segment database. Information and articulation, computing path planning; then the mobile terminal can be The trajectory information including the average elevation, the driving direction, the video, the photo, and the connection relationship together with the mark and the prompt are sent to the mobile terminal together with the calculated path planning solution; the calculating the connection relationship refers to accumulating on a certain road segment The number of consecutive trajectories formed by each mobile terminal on a straight line or a turn, traveling across a node to an adjacent road segment, when the number falls within a set threshold time within a set time period, or when In a set time zone, when the ratio of the continuous trajectory is compared with the number of related trajectories and the ratio falls within a set threshold, it is confirmed that the two sections have the direction in which the trajectory runs. Cohesion.
可选的,上述利用所述轨迹信息和终端已有实时路径规划方案更新和完善云平台内部的动态路
段数据库,是指云平台根据多个移动终端动态的实时上传的终端已有实时路径规划方案,及所涉及到的路段的较近一段时间的即时动态阻抗,计算出未来某指定时间某一路段上的移动终端的一个预测数量,然后根据这个预测数量找出云平台中存储的与此数量相对应的该路段的上某一段时间内的即时动态阻抗的加权平均值,作为该路段的预测动态阻抗,与对应时间一起存储到云平台的一个数据库中,当一个移动终端提出某一特定的路径规划时,云平台根据这个所述预测动态阻抗,预测未来某指定时间、某指定路段的交通拥堵状况,并按移动终端要求计算出一个路径规划方案,无线传输给移动终端。Optionally, the foregoing uses the trajectory information and the existing real-time path planning scheme of the terminal to update and improve the dynamic path inside the cloud platform.
The segment database refers to the real-time path planning scheme of the terminal that is dynamically uploaded by the cloud platform according to the dynamics of multiple mobile terminals, and the instantaneous dynamic impedance of the relevant segment of the road segment, and calculates a certain section of the road at a specified time in the future. a predicted quantity of the mobile terminal, and then finding a weighted average of the instantaneous dynamic impedance of the road segment corresponding to the quantity stored in the cloud platform according to the predicted quantity, as the predicted dynamics of the road segment The impedance is stored in a database of the cloud platform along with the corresponding time. When a mobile terminal proposes a specific path plan, the cloud platform predicts the traffic congestion of a specified time segment and a specified road segment according to the predicted dynamic impedance. The situation, and calculate a path planning scheme according to the requirements of the mobile terminal, and wirelessly transmit to the mobile terminal.
可选的,所述云平台根据这些更新和完善了的路段数据库数据,计算出相应的路径规划具体包括:Optionally, the cloud platform calculates, according to the updated and improved road segment database data, the corresponding path plan specifically includes:
其更新完善的方式和计算路径规划的方法可以根据需要,将上述方法供的技术方案进行组合使用。The method of updating and perfecting and calculating the path planning method can combine the technical solutions provided by the above methods as needed.
移动终端在接到云平台无线发送的路径规划方案后,会有三种情况:After the mobile terminal receives the path planning scheme for wireless transmission by the cloud platform, there are three cases:
a、云平台中的路段数据库数据和移动终端的完全相同,移动终端则按照云平台做出的路径规划方案,直接用本地的对应路段拼接出来;a. The data of the link database in the cloud platform is exactly the same as that of the mobile terminal, and the mobile terminal directly splices the corresponding corresponding road segment according to the path planning scheme made by the cloud platform;
b、云平台内的地图与移动终端内的地图同系统不同版本,或虽然同系统同版本但路段数据库中的数据不同,这时主要产生的问题是云平台上有的路段但移动终端地图却没有,为解决这个问题,应事先通过特殊的数据库设计及拓扑关系的建立,尽可能使两个同系统不同版本的路段数据库具有高兼容性,这样,云平台就可以先通过检测,将共同拥有的连续的路段数据信息按序排列出来发送给终端,然后移动终端按照上述a.中的方法执行;对于云平台中有但移动终端中没有的路段数据部分,云平台则将这部分路段数据中的位置点的经纬度数据发送给移动终端,移动终端再根据这些经纬度数据找出对应的位置点,并连线且在显示屏中显示出来,同时在语音提示中提示:“未知道路,请按轨迹信息小心驾驶”。b. The map in the cloud platform and the map in the mobile terminal are different versions of the system, or although the data in the road segment database is different from the same version of the system, the main problem is that there are some segments on the cloud platform but the mobile terminal map is No, in order to solve this problem, the special database design and topology relationship should be established in advance, so as to make the two sections of the same system different versions of the database have high compatibility, so that the cloud platform can pass the detection and will jointly own The continuous road segment data information is sequentially arranged and sent to the terminal, and then the mobile terminal performs according to the method in a. above; for the part of the cloud platform that is not in the mobile terminal, the cloud platform will use the data in the part of the road segment. The latitude and longitude data of the location point is sent to the mobile terminal, and the mobile terminal further finds the corresponding location point according to the latitude and longitude data, and connects and displays it in the display screen, and prompts in the voice prompt: “Unknown road, please press the track Information is carefully driven."
C、对于不同系统的电子地图,将依据国际或国家相关标准,将路段信息全部转换成轨迹信息,即将全部的路径规划方案以轨迹位置点经纬度数据的形式发送给移动终端,移动终端在屏幕上据此画出连线来供驾驶者参考,同时伴随发送语音提示:“轨迹导航,请按轨迹小心驾驶。”这样,将有利于最大限度的服务于各种不同的客户。C. For electronic maps of different systems, the road segment information will be converted into track information according to international or national relevant standards, that is, all path planning schemes will be sent to the mobile terminal in the form of track position point latitude and longitude data, and the mobile terminal is on the screen. According to this, draw a connection for the driver's reference, accompanied by a voice prompt: "Track navigation, please drive carefully according to the trajectory." This will help maximize the service to a variety of different customers.
需要说明的是,上述说明的轨迹信息,既可以是包括采用GPS/DR、BD2(第二代北斗导航系统)/DR移动终端定位模块的卫星定位技术、移动通信基站定位技术采集的轨迹信息,也可以是通过采用RFID识别技术、红外或激光扫描技术之类的电子识别技术,识别装载在车辆上的电子标签来获取的轨迹信息,还可以包括以视频及图像信息方式获取的轨迹信息,上述轨迹信息的采集方式不应受采集方法的限制。It should be noted that the trajectory information described above may be trajectory information collected by a satellite positioning technology using a GPS/DR, BD2 (second generation Beidou navigation system)/DR mobile terminal positioning module, and a mobile communication base station positioning technology. It may also be an trajectory information acquired by using an electronic identification technology such as an RFID recognition technology, an infrared or a laser scanning technology to identify an electronic tag loaded on the vehicle, and may also include trajectory information acquired by video and image information, The way the track information is collected should not be limited by the acquisition method.
为保护用户的隐私,所述轨迹信息及终端已有实时路径规划方案的采集可以采用匿名方式获取。移动终端与云平台之间的轨迹信息的上传或路径规划的接收,其无线通信方式也可以为多种,包括卫星通信、北斗卫星导航系统的短信通信、WiFi、GPRS、2G、3G或4G技术,本发明具体实施方式并不局限于何种无线通信方式。
To protect the privacy of the user, the trajectory information and the collection of the real-time path planning scheme of the terminal may be acquired anonymously. The uploading of the trajectory information between the mobile terminal and the cloud platform or the reception of the path planning may also be performed in a variety of ways, including satellite communication, SMS communication of the Beidou satellite navigation system, WiFi, GPRS, 2G, 3G or 4G technologies. The specific embodiments of the present invention are not limited to any wireless communication method.
需要说明的是,上述轨迹信息可以包括:轨迹各点的经度、纬度、高程、二维或三维速度、二维或三维运动方向、轨迹的数量、轨迹所属移动终端的代码、视频及图像多种参量,以及所述多种参量的获取时间;所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量和轨迹的获取时间区域在内的轨迹信息中的多种参量,生成和更新未知道路上的路段数据、所有路段上的即时动态阻抗、所有路段上的模拟交通限制信息。其具体方法之一为:云平台接收到轨迹信息后,先对其进行滤波处理,去除异常或偏差过大的杂波,然后按照一定的方法将轨迹信息中的位置数据同GIS数据库中的原有的路段数据相匹配,如成功则落入该路段数据中,即将轨迹与结点路段对应的点的数据更改为路段对应点的数据,并根据轨迹的获取时间赋予该路段即时动态阻抗权值;如不成功,则存储到另外一个数据库中,并在这个数据库中,对位置邻近的轨迹进行整理合并,生成一条或多条模拟道路,当在一个指定时间区域内,所述模拟道路上的轨迹数量达到一定值时,则按照一定的方法分割并模拟生成新的路段。It should be noted that the trajectory information may include: longitude, latitude, elevation, two-dimensional or three-dimensional velocity, two-dimensional or three-dimensional motion direction, number of trajectories, code of the mobile terminal to which the trajectory belongs, video and image a parameter, and an acquisition time of the plurality of parameters; the updating and perfecting the dynamic road segment database inside the cloud platform refers to generating a plurality of parameters in the trajectory information including the number of trajectories and the acquisition time region of the trajectory And update road segment data on unknown roads, instantaneous dynamic impedance on all road segments, and simulated traffic restriction information on all road segments. One of the specific methods is: after receiving the trajectory information, the cloud platform first filters the trajectory to remove the clutter with abnormal or excessive deviation, and then according to a certain method, the position data in the trajectory information is the same as the original in the GIS database. Some road segments have data matching. If they succeed, they fall into the data of the road segment. The data of the point corresponding to the track and the link segment is changed to the data of the corresponding point of the link, and the instantaneous dynamic impedance weight of the segment is given according to the acquisition time of the track. If unsuccessful, store it in another database, and in this database, sort and merge the adjacent tracks to generate one or more simulated roads, when in a specified time zone, on the simulated road When the number of tracks reaches a certain value, a new road segment is divided and simulated according to a certain method.
另外,还可根据多个终端已有实时路径规划方案生成和更新路段预测动态阻抗。所述终端已有实时路径规划方案是指移动终端正在使用的、从本次上传开始时的所在的地点到目的地的一个路径规划方案;所述即时动态阻抗是指根据已接收到的所述多个移动终端的轨迹信息,计算某路段某时间区域的加权平均耗时,得出结果即为所述某时间区域某路段的即时动态阻抗;所述预测动态阻抗是指根据多个移动终端上传的多个终端已有实时路径规划方案,结合云平台中的历史数据,计算未来某时间区域某路段的耗时,得出结果即为所述未来某时间区域某路段的预测动态阻抗;所述所有路段是指包括新生成的路段和原有路段。In addition, the segment prediction dynamic impedance can be generated and updated according to the existing real-time path planning scheme of multiple terminals. The real-time path planning scheme of the terminal refers to a path planning scheme used by the mobile terminal from the location where the uploading starts to the destination; the instantaneous dynamic impedance refers to the received The trajectory information of the plurality of mobile terminals is used to calculate the weighted average time of a certain time zone of a certain road segment, and the result is the instantaneous dynamic impedance of a certain section of the certain time zone; the predicted dynamic impedance refers to uploading according to multiple mobile terminals. The multiple terminals have a real-time path planning scheme, and combine the historical data in the cloud platform to calculate the time consumption of a certain section of the future time zone, and the result is the predicted dynamic impedance of a certain section of the future time zone; All road segments are those that include newly generated road segments and original road segments.
需要说明的是,本申请中所述的轨迹获取时间,是指构成轨迹的各个位置点的获取时间所组成的一个时间集合,所述位置点的获取时间,是指移动终端在采集到所述位置点经纬度数据时所处的时刻,因为移动终端所在的时刻和采集到数据的时刻可能会有一个误差,所以这个获取时间一般会稍微滞后于移动终端实际所在该位置点的时间。但在本技术里,一般忽略了这个时间差异。It should be noted that the trajectory acquisition time described in the present application refers to a time set formed by the acquisition time of each location point constituting the trajectory, and the acquisition time of the location point refers to that the mobile terminal collects the When the latitude and longitude data is located, there may be an error in the time when the mobile terminal is located and the time at which the data is collected. Therefore, the acquisition time generally lags slightly behind the time at which the mobile terminal is actually located. However, in this technique, this time difference is generally ignored.
需要说明的是,本技术中所述的交通限制信息,是指包括:禁止向左转弯、禁止向右转弯、禁止掉头、禁止直行的交通禁令标志类信息和向左转弯、向右转弯、允许掉头、单行路只准直行的交通指示标志类信息。It should be noted that the traffic restriction information described in the present technology includes: prohibiting a turn to the left, prohibiting a turn to the right, prohibiting a U-turn, prohibiting a straight-line traffic prohibition sign information, turning left, turning right, allowing U-turn, one-way road only traffic signs information.
所述云平台根据预测动态阻抗,预测未来某指定时间、某指定路段的交通拥堵状况,并按移动终端要求计算出一个路径规划方案,无线发送给移动终端;其意义还在于:一方面可以用来预测及统筹规划车辆的流量分布,另一方面,当云平台和移动终端对轨迹信息的采集传输速度、路径规划方案的计算速度及无线传输速度足够快时,并辅以相关车辆之间的所述轨迹信息的直接交流,还可以通过自动报警、自动规避的方式,用来防止车辆之间的碰撞。The cloud platform predicts the traffic congestion condition of a certain specified time and a certain road section according to the predicted dynamic impedance, and calculates a path planning scheme according to the requirements of the mobile terminal, and transmits the data to the mobile terminal wirelessly; the meaning is also: To predict and coordinate the traffic distribution of the vehicle. On the other hand, when the cloud platform and the mobile terminal collect the transmission speed of the trajectory information, the calculation speed of the path planning scheme and the wireless transmission speed are fast enough, and supplemented by the relevant vehicles. The direct communication of the trajectory information can also be used to prevent collisions between vehicles by means of automatic alarm and automatic evasion.
需要说明的的是,所述计算衔接关系,是指累加某个路段上的每一个移动终端在直行或转弯过程中跨越结点行驶到相邻的路段时形成的连续轨迹的所得到的数量,当这个所述数量的值、或所述数量同其他相关轨迹数量相比的相对值,在一设定的时间区域内大于一个设定的值时,则确认为这两个路段以所跨越的结点为衔接点、在这个轨迹运行的方向上有衔接关系;当这个所述数量的值、或所述数量同其他相关轨迹数量相比的相对值,在一设定的时间区域内小于一个设定的值时,则确
认为这两个路段以所跨越的结点为衔接考察点、在这个轨迹运行的方向上没有衔接关系;而在这里所述的没有衔接关系,包括物理条件上的如立交桥上下错层的道路、护栏、沟壑的限制;还包括交通规则的上的如不许直行、不许转弯的限制。It should be noted that the calculating the connection relationship refers to accumulating the number of continuous trajectories formed when each mobile terminal on a certain road segment travels to the adjacent road segment during the straight or turning process. When the value of the quantity, or the relative value of the quantity compared with the number of other related trajectories, is greater than a set value within a set time zone, it is confirmed that the two road sections are spanned The node is a joint point, and there is a cohesive relationship in the direction in which the trajectory runs; when the value of the quantity, or the relative value of the quantity compared with the number of other related trajectories, is less than one in a set time zone When setting the value, it is true
It is considered that the two sections are connected by the nodes they cross, and there is no connection relationship in the direction in which the trajectory runs. However, there is no connection relationship here, including the physical conditions such as the road of the upper and lower layers of the overpass. Limits on guardrails and gullies; also include restrictions on traffic rules that are not allowed to go straight and are not allowed to turn.
综上所述,本技术的实施,将对ITS智能交通系统、车联网应用技术的发展及我国智慧城市的建设起到一定的推动作用。In summary, the implementation of this technology will play a certain role in promoting the development of ITS intelligent transportation system, vehicle networking application technology and the construction of smart cities in China.
本发明具体实施方式还提供一种云平台,该云平台包括:多台智能设备,该智能设备具体可以:计算机或服务器,所述智能设备的硬件结构图如图2所示,包括:处理器201、存储器202、通信接口203和总线204。The embodiment of the present invention further provides a cloud platform, which includes: a plurality of smart devices, the smart device may specifically be: a computer or a server, and the hardware structure diagram of the smart device is as shown in FIG. 2, including: a processor 201. Memory 202, communication interface 203, and bus 204.
处理器201、存储器202、通信接口203通过总线204相互连接;总线204可以是工业标准架构体系(Industry Standard Architecture,ISA)总线或外围组件互联(英文:Peripheral Component Interconnect,简称:PCI)总线等。The processor 201, the memory 202, and the communication interface 203 are connected to each other through a bus 204. The bus 204 may be an Industry Standard Architecture (ISA) bus or a Peripheral Component Interconnect (PCI) bus.
上述的处理器201可以是通用处理器,包括中央处理器(英文:central processing unit,简称CPU)、网络处理器(英文:network processor,简称NP),当然也可以为数字信号处理器(英文:Digital Signal Processing,简称:DSP)等。The above-mentioned processor 201 may be a general-purpose processor, including a central processing unit (English: central processing unit, CPU for short), a network processor (English: network processor, referred to as NP), and of course, may also be a digital signal processor (English: Digital Signal Processing, referred to as DSP).
存储器202,用于存放程序和动态路段数据库。具体地,程序可以包括程序代码,所述程序代码包括计算机操作指令,该程序用于指示处理器201发出计算机操作指令。存储器202可能包含高速随机存储器(英文:random-access memory,简称:RAM)存储器,也可能还包括非易失性存储器(non-volatile memory),例如至少一个磁盘存储器。The memory 202 is configured to store a program and a dynamic link database. In particular, the program can include program code, the program code including computer operating instructions for instructing the processor 201 to issue computer operating instructions. The memory 202 may include a high-speed random access memory (RAM) memory, and may also include a non-volatile memory such as at least one disk memory.
通信接口203,用于接收或发送数据。上述数据具体可以为:报文、轨迹信息或路径规划信息等数据,具体地,该通信接口203可以为通信端口,该通信端口包括但不限于无线通信端口或有线通信端口。The communication interface 203 is configured to receive or send data. The data may be: a packet, a track information, or a path planning information. Specifically, the communication interface 203 may be a communication port, and the communication port includes but is not limited to a wireless communication port or a wired communication port.
通信接口203实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,处理器201然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;当通信接口203接收到移动终端提出的某一有特定要求的路径规划请求时,处理器201根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出和某一有特定要求的路径规划请求相应的路径规划,然后将所述相应的路径规划以无线方式发送给移动终端;The communication interface 203 wirelessly receives multiple track information uploaded by multiple mobile terminals in real time or has a real-time path planning scheme for multiple terminals, and the processor 201 then updates the existing track path plan by using the multiple track information or multiple terminals. And perfecting the dynamic link database inside the cloud platform; when the communication interface 203 receives a certain path planning request that is requested by the mobile terminal, the processor 201 is configured according to the dynamic segment database data inside the cloud platform that is updated and improved. Calculating a path plan corresponding to a path planning request with a specific requirement, and then transmitting the corresponding path plan to the mobile terminal in a wireless manner;
上述终端已有实时路径规划方案是指移动终端内部已有的且正在使用的、从所述移动终端本次上传开始时的所在地到目的地的一个路径规划方案;The real-time path planning scheme of the foregoing terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;
所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片图像及获取时间,轨迹所属移动终端的代码;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the track belongs;
所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据、所有路段的即时动态阻抗和所有路段的模拟交通限制信息,另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路
段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating the road segment data on the unknown road, the instantaneous dynamic impedance of all the road segments, and all the road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Simulating traffic restriction information, and generating and updating all the roads according to the existing real-time path planning scheme and trajectory history data of the plurality of terminals
The predicted dynamic impedance of the segment;
所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指构成轨迹各点的经纬度的获取时间所组成的一个和各点对应的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory; The acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
可选的,处理器201具体用于,当多个移动终端上传的轨迹信息不能匹配到云平台的动态路段数据库中原有的路段数据上时,处理器201将这些不能匹配的所述轨迹信息去除噪声,按一定方法整理合并成一条或多条模拟道路,并暂存到动态路段数据库中,同时累加所述模拟道路中的轨迹数量;当在某设定一时间区间内,某条所述模拟道路上的轨迹数量累加到某一设定阈值时,所述处理器将这条模拟道路转变成一条或几条新的临时或永久的新生成路段数据,存储到动态路段数据库中,处理器201还根据实时上传的新的轨迹信息对所述的新生成路段数据不断更新。Optionally, the processor 201 is configured to: when the track information uploaded by the multiple mobile terminals cannot match the original road segment data in the dynamic road segment database of the cloud platform, the processor 201 removes the track information that cannot match. Noise, according to a certain method, merged into one or more simulated roads, and temporarily stored in the dynamic road segment database, and accumulate the number of tracks in the simulated road; when in a certain time interval, a certain simulation When the number of tracks on the road is added to a certain threshold, the processor converts the simulated road into one or several new temporary or permanent newly generated road segment data, and stores the data in the dynamic road segment database, and the processor 201 The newly generated road segment data is also continuously updated according to the new track information uploaded in real time.
可选的,处理器201具体用于根据多个移动终端实时上传的轨迹的数量及轨迹的获取时间,计算出某一路段上某一时间区域的轨迹的平均耗时,并把所述的平均耗时作为一个即时动态阻抗存储在一个数据库中,所述某一路段是原有道路上的路段或是未知道路上新生成的路段;Optionally, the processor 201 is specifically configured to calculate, according to the number of trajectories uploaded by the mobile terminal in real time and the acquisition time of the trajectory, an average time consuming of the trajectory of a certain time zone on a certain road segment, and average the trajectory The time-consuming is stored as a real-time dynamic impedance in a database, and the certain road segment is a road segment on the original road or a newly generated road segment on the unknown road;
当移动终端提出的某一特定要求的路径规划请求为:最短时间的路径规划请求时,所述处理器根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出某一有特定要求的路径规划请求相应的路径规划具体包括:所述处理器用包含了这些即时动态阻抗的数据库数据,计算总体耗时最短的路径规划。When the path planning request of a specific requirement proposed by the mobile terminal is: the shortest time path planning request, the processor calculates a certain specific according to the dynamic road segment database data inside the updated and improved cloud platform. The corresponding path planning request corresponding path planning specifically includes: the processor uses the database data including the instantaneous dynamic impedance to calculate the overall shortest path planning.
可选的,处理器201具体用于将包括在原有道路和未知道路上行驶的众多移动终端上传的轨迹的获取时间存储到云平台的动态数据库中,并将所述轨迹的获取时间与所述轨迹的获取时间对应路段相关联;当移动终端设定一时间区域,并提出请求:当一些存储在所述动态数据库中的轨迹获取时间落入所述时间区域时,找出这些获取时间所对应的轨迹,再找出所述对应的轨迹所在的路段,然后用这些路段拼接出一个路径规划,处理器201则根据移动终端的请求用符合条件的路段,计算出路径规划。Optionally, the processor 201 is specifically configured to store, in a dynamic database of the cloud platform, an acquisition time of the trajectory uploaded by the plurality of mobile terminals that are used on the original road and the unknown road, and acquire the trajectory of the trajectory and the The acquisition time of the trajectory is associated with the road segment; when the mobile terminal sets a time zone, and makes a request: when some trajectory acquisition time stored in the dynamic database falls into the time zone, it is found that the acquisition time corresponds to The trajectory is further found out the path segment where the corresponding trajectory is located, and then a path plan is spliced by using the road segments, and the processor 201 calculates the path plan according to the request of the mobile terminal by using the qualified road segment.
可选的,处理器201将众多终端上传的某路段上的轨迹的数量,存储到云平台的数据库中,并与对应路段相关联;当移动终端设定一个数量阈值,并提出当一些路段上的轨迹数量落入这个数量阈值时,找出这些路段,然后用这些路段拼接出一个路径规划的请求时,处理器201则根据移动终端的请求用符合条件的路段,拼接出路径规划。Optionally, the processor 201 stores the number of tracks on a certain road segment uploaded by the plurality of terminals in a database of the cloud platform, and is associated with the corresponding road segment; when the mobile terminal sets a threshold number, and proposes to be on some road segments When the number of trajectories falls within the threshold of the number, the road segments are found, and then the request for path planning is spliced by the road segments, and the processor 201 splices out the path plan according to the request of the mobile terminal.
可选的,处理器201具体用于通过检验在未知道路和原有道路某一时间区域、某一指定路段上的轨迹数量,模拟生成允许转弯、禁止转弯交通限制信息、允许掉头、禁止掉头交通限制信息或单行线交通限制信息。Optionally, the processor 201 is specifically configured to simulate to allow turning, prohibit turning traffic restriction information, allow U-turn, and prohibit U-turn traffic by checking the number of tracks on a certain time zone and a certain road section of the unknown road and the original road. Restrict information or one-way traffic restrictions.
可选的,处理器201具体用于检验两个相交的路段是否共同拥有连续的同一移动终端形成的某行驶方向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的绝对数量、或者同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照轨迹行驶方向可以转弯的交通限制信息,存储到一个特殊的数据库中,反之,当这个计算结果小于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照轨迹行驶方向禁止
转弯的交通限制信息,存储到一个特殊的数据库。Optionally, the processor 201 is specifically configured to check whether two intersecting road segments have a continuous trajectory of a certain traveling direction formed by the same mobile terminal, and calculate an absolute number of such trajectories in a set time region. Or the relative quantity compared with the relevant trajectory. When the calculation result is greater than a predetermined value, the simulation generates traffic restriction information between the two road sections that can be turned according to the trajectory direction of the intersecting node. Stored in a special database. Conversely, when the result of this calculation is less than a predetermined value, the simulated generation of the intersection between the two links is prohibited according to the direction of the trajectory.
Turn traffic restrictions information to a special database.
可选的,处理器201具体用于检验某一个路段是否存在以某形值点为转折点的同一移动终端连续形成的正向和反向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的绝对数量,或者,同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这个路段之间的可以在这个转折点按照所述轨迹转折方向掉头的交通限制信息,存储到一个特殊的数据库中,反之,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段之间的在这个转折点按照所述轨迹转折方向禁止掉头的交通限制信息,存储到一个特殊的数据库中。Optionally, the processor 201 is specifically configured to check whether a certain road segment has a forward and reverse trajectory continuously formed by the same mobile terminal with a shape point as a turning point, and calculate the trajectory in a set time zone. The absolute number of the trajectories, or the relative number of the trajectories compared with the related trajectories, when the calculation result is greater than a predetermined value, the simulation between the generated segments can be turned around at the turning point according to the trajectory turning direction The traffic restriction information is stored in a special database. Conversely, when the calculation result is less than a preset value, the simulation generates a traffic restriction between the road segments that prohibits the U-turn in the turning direction of the turning point. Information is stored in a special database.
可选的,处理器201具体用于检验某个的路段某个方向的移动终端形成的轨迹数量,并计算在一个设定的时间区域内这类所述轨迹的绝对数量,或者,同相反方向的或其他相关的轨迹相比较的相对数量,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段在这个所述方向的禁止通行的交通限制信息,存储到一个特殊的数据库中。Optionally, the processor 201 is specifically configured to check the number of tracks formed by the mobile terminal in a certain direction of a certain road segment, and calculate the absolute number of such tracks in a set time region, or the same direction The relative number of comparisons of other or related trajectories. When the result of the calculation is less than a predetermined value, the traffic restriction information of the prohibited passage in the direction of the road segment is simulated and stored in a special database. .
可选的,处理器201具体用于先采用静态的常规的最短路径计算方法计算出n条总体距离最短的路径规划方案,再在n条最短路径规划方案中根据所在路段上的即时动态阻抗选出总体耗时最短的一条路径规划,所述路段包括:原有道路和未知道路上的路段。Optionally, the processor 201 is specifically configured to calculate a path planning scheme with the shortest overall distance by using a static conventional shortest path calculation method, and then select, according to the instantaneous dynamic impedance on the road segment, the n shortest path planning schemes. A path plan with the shortest overall time consuming, the road segments include: original roads and road sections on unknown roads.
可选的,上述静态的常规的最短路径计算方法,是指A*启发式搜索算法;所述A*启发式搜索算法是用来根据所述更新和完善了的云平台内部的动态路段数据库数据计算出n条总体距离最短的路径规划方案的;所述A*启发式搜索算法,包括下限为0的A*启发式搜索算法的一种特例:dijkstra算法。Optionally, the static conventional shortest path calculation method refers to an A * heuristic search algorithm; and the A * heuristic search algorithm is used to dynamically update the dynamic road segment database data according to the cloud platform. The path planning scheme with the shortest overall distance is calculated; the A * heuristic search algorithm includes a special case of the A * heuristic search algorithm with a lower bound of 0: the dijkstra algorithm.
可选的,上述利用所述多个轨迹信息更新和完善在云平台内部的动态路段数据库,是指将根据轨迹信息模拟生成的新的路段数据后,将新的路段数据同原有路段数据一起存储在一个以邻接表方式表达的数据库中。Optionally, the updating and improving the dynamic link database in the cloud platform by using the plurality of trajectory information refers to: after the new link data generated by the trajectory information is simulated, the new link data is combined with the original link data. Stored in a database expressed in a contiguous table.
可选的,处理器201具体用于将轨迹信息中的高程和二维或三维运动方向信息同所在路段相关联并加权平均后存储在动态路段数据库中;当云平台用包括高架桥在内的上下高度不同但水平面位置相近或相同的、或其它高度相同但水平位置接近的近似路段进行路径规划时,云平台首先检验所述近似路段结点的经纬度坐标,当两个路段对应结点的经度坐标值之差和纬度坐标值之差的绝对值同时小于一个设定阈值时,则自动读取行驶在其上轨迹的平均高程和行驶方向,同时计算与前后相邻路段的衔接关系,并进行标记和提示,然后将所述表示高程、行驶方向和衔接关系的标记、提示和计算出的路径规划方案一起发送给移动终端;所述计算与前后相邻路段的衔接关系,是指计算同一移动终端同一方向跨越相邻的路段的连续轨迹的绝对数量和相对数量,当所述绝对数量和相对数量在一设定的时间区域内落入设定的数量阈值时,则确认为这两个路段在这个轨迹运行的方向有衔接关系。Optionally, the processor 201 is specifically configured to associate the elevation and the two-dimensional or three-dimensional motion direction information in the trajectory information with the road segment and weight the average, and store the information in the dynamic road segment database; when the cloud platform uses the upper and lower bridges including the viaduct When the height is different but the horizontal planes are similar or identical, or other similar sections with the same height but close horizontal position are used for path planning, the cloud platform first checks the latitude and longitude coordinates of the approximate road segment nodes, and the longitude coordinates of the corresponding nodes of the two road segments. When the absolute value of the difference between the value difference and the latitude coordinate value is less than a set threshold value at the same time, the average elevation and the traveling direction of the trajectory traveling thereon are automatically read, and the connection relationship with the adjacent road segments is calculated and marked. And prompting, and then sending the indication, the prompt indicating the elevation, the driving direction and the connection relationship, and the calculated path planning scheme to the mobile terminal; the calculating the connection relationship with the adjacent road segments refers to calculating the same mobile terminal The absolute number and relative number of consecutive trajectories spanning adjacent segments in the same direction, when The number and relative amount of the fall threshold number is set in a time region is set, it is confirmed for both engagement sections has a relationship in the direction of the running track.
可选的,所述利用所述轨迹信息或终端已有实时路径规划方案更新和完善云平台内部的动态路段数据库,是指云平台根据多个移动终端动态的实时上传的终端已有实时路径规划方案,及所涉及到的路段的一段时间范围内的即时动态阻抗,计算出未来某指定时间某一路段上的移动终端的一个预测数量,然后根据所述预测数量找出云平台中存储的与所述预测数量相对应的该路段的上某一
段时间内的即时动态阻抗的加权平均值,作为该路段的预测动态阻抗,将所述预测动态阻抗与对应时间一起存储到云平台的动态路段数据库中,当一个移动终端提出某一特定的路径规划时,云平台根据所述预测动态阻抗,预测未来某指定时间、某指定路段的交通拥堵状况,并按移动终端提出某一特定的路径规划的要求计算出一个路径规划方案,发送给移动终端。Optionally, the using the trajectory information or the existing real-time path planning scheme of the terminal to update and improve the dynamic road segment database inside the cloud platform refers to the real-time path planning of the terminal that is dynamically uploaded by the cloud platform according to dynamics of multiple mobile terminals. The solution, and the instantaneous dynamic impedance within a certain period of time of the road segment involved, calculate a predicted number of mobile terminals on a certain road segment at a specified time in the future, and then find the stored and stored in the cloud platform according to the predicted quantity. The predicted quantity corresponds to a certain one of the road segments
The weighted average of the instantaneous dynamic impedance during the segment time is used as the predicted dynamic impedance of the road segment, and the predicted dynamic impedance is stored together with the corresponding time in the dynamic road segment database of the cloud platform, when a mobile terminal proposes a specific path During the planning, the cloud platform predicts the traffic congestion condition of a specified time and a specified road section according to the predicted dynamic impedance, and calculates a path planning solution according to the requirement of the specific terminal planning of the mobile terminal, and sends the path planning plan to the mobile terminal. .
本领域技术人员可以理解,本发明实施例提供的技术方案全部或部分步骤是可以通过程序指令相关的硬件来完成。比如可以通过计算机运行程来完成。该程序可以存储在可读取存储介质,例如,随机存储器、磁盘、光盘等。Those skilled in the art can understand that all or part of the technical solutions provided by the embodiments of the present invention can be completed by using related hardware of the program instructions. For example, it can be done by computer running. The program can be stored in a readable storage medium such as a random access memory, a magnetic disk, an optical disk, or the like.
以上所述仅为本发明的较佳实施例而已,并不用以限制本发明,凡在本发明的具体实施方式之内所作的等同替换或改进等,均应包含在本发明的保护范围之内。
The above is only the preferred embodiment of the present invention, and is not intended to limit the present invention. All equivalent substitutions or improvements made within the specific embodiments of the present invention are included in the protection scope of the present invention. .
Claims (28)
- 一种动态的导航路径规划方法,其特征在于,所述方法包括:A dynamic navigation path planning method, the method comprising:云平台实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;The cloud platform receives multiple track information uploaded by multiple mobile terminals in real time or multiple real-time path planning schemes of multiple terminals, and then uses the multiple track information or multiple terminals to have a real-time path planning solution to update and improve the cloud platform. Internal dynamic road segment database;当云平台接收到移动终端提出的某一有特定要求的路径规划请求时,云平台根据更新和完善了的所述云平台内部的动态路段数据库数据,计算出对应的路径规划,然后将所述对应的路径规划以无线方式发送给移动终端;When the cloud platform receives a certain path planning request that is requested by the mobile terminal, the cloud platform calculates a corresponding path plan according to the updated and improved dynamic road segment database data of the cloud platform, and then the The corresponding path plan is sent to the mobile terminal in a wireless manner;所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片及获取时间,轨迹所属移动终端的代码;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo and acquisition time, the code of the mobile terminal to which the track belongs;所述终端已有实时路径规划方案是指移动终端内部已有的且正在使用的、从所述移动终端本次上传开始时的所在地到目的地的一个路径规划方案;The real-time path planning scheme of the terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;所述更新和完善云平台内部的动态路段数据库,是指包括:根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据,生成和更新所有路段的即时动态阻抗,生成和更新所有路段的模拟交通限制信息;另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform includes: generating and updating road segment data on the unknown road according to the trajectory information including the number of trajectories and the acquisition time of the trajectory, and generating and updating the instant of all the road segments. Dynamic impedance, generating and updating simulated traffic restriction information of all road segments; in addition, generating and updating predicted dynamic impedances of all road segments according to the existing real-time path planning scheme and trajectory historical data of the plurality of terminals;所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指由构成轨迹各点的经纬度的获取时间所组成的一个和所述各点对应关联的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the points formed by the acquisition time of the latitude and longitude constituting the points of the trajectory; The acquisition time of the latitude and longitude of each point of the trajectory refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- 根据权利要求1所述的方法,其特征在于,所述生成和更新未知道路上的路段数据,具体包括:The method according to claim 1, wherein the generating and updating the link data on the unknown road comprises:当移动终端在未知道路上行驶并上传轨迹信息时,云平台将所述轨迹信息中的位置信息,去除异常点及噪声并按照一定方法整理合并成一条或多条模拟道路,暂存到动态路段数据库中,同时累加所述模拟道路中的轨迹数量;当在某一设定的时间区域内,合并在某条所述模拟道路上的累加的所述轨迹数量落入某一设定阈值时,云平台将所述某条所述模拟道路转变成一条或几条新的临时或永久的新生成路段数据,存储到动态路段数据库中,然后云平台根据实时上传的新的轨迹信息对所述新生成路段及相关数据不断更新;When the mobile terminal travels on the unknown road and uploads the trajectory information, the cloud platform removes the abnormal point and noise from the position information in the trajectory information and combines them into one or more simulated roads according to a certain method, and temporarily stores them in the dynamic road section. In the database, the number of tracks in the simulated road is simultaneously accumulated; when the number of the accumulated tracks accumulated on a certain simulated road falls within a certain set time period, The cloud platform converts the certain simulated road into one or several new temporary or permanent newly generated road segment data, and stores the data in the dynamic road segment database, and then the cloud platform pairs the new track information according to the new track information uploaded in real time. Generate road segments and related data are continuously updated;所述未知道路是指原有的所述动态路段数据库中没有对应数据的道路。The unknown road refers to a road in the original dynamic road segment database that does not have corresponding data.
- 根据权利要求1所述的方法,其特征在于,所述计算出对应的路径规划具体包括:The method according to claim 1, wherein the calculating the corresponding path plan specifically comprises:云平台根据多个移动终端实时上传的轨迹的数量及轨迹的获取时间,计算出某一路段上某一时间区域的轨迹的平均耗时,并把所述的平均耗时作为一个即时动态阻抗同所述时间区域一起存储在一个数据库中,所述某一路段是指原有道路上的路段或未知道路上新生成的路段;The cloud platform calculates the average time consuming of the trajectory of a certain time zone on a certain road segment according to the number of trajectories uploaded by the mobile terminal in real time and the acquisition time of the trajectory, and uses the average time consumption as an instantaneous dynamic impedance. The time zones are stored together in a database, and the certain road segment refers to a road segment on the original road or a newly generated road segment on the unknown road;当移动终端提出的某一有特定要求的路径规划请求为:最短时间的路径规划请求时,所述云平台根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出对应的路径规划具体包括: 云平台用包含了这些即时动态阻抗的数据库数据,计算出总体耗时最短的路径规划。When the path planning request of the specific requirement proposed by the mobile terminal is: the shortest time path planning request, the cloud platform calculates the corresponding path according to the dynamic road segment database data inside the updated and improved cloud platform. The plan specifically includes: The cloud platform uses the database data that contains these instantaneous dynamic impedances to calculate the overall time-consuming path plan.
- 根据权利要求1所述方法,其特征在于,所述计算出对应的路径规划具体包括:The method according to claim 1, wherein the calculating the corresponding path plan specifically comprises:云平台将包括在原有道路和未知道路上行驶的多个移动终端上传的轨迹的获取时间存储到云平台的动态数据库中,并将所述轨迹的获取时间与对应轨迹所在的路段相关联;当云平台或移动终端设定一时间区域,并提出请求:当一些存储在所述动态路段数据库中的轨迹获取时间落入所述时间区域时,找出该获取时间所对应的轨迹,再找出所述对应的轨迹所在的路段,然后用这些路段拼接出一个路径规划;云平台则根据云平台或移动终端的请求用符合条件的路段,计算出相应的路径规划。The cloud platform stores the acquisition time of the trajectory uploaded by the plurality of mobile terminals traveling on the original road and the unknown road into a dynamic database of the cloud platform, and associates the acquisition time of the trajectory with the road segment where the corresponding trajectory is located; The cloud platform or the mobile terminal sets a time zone, and makes a request: when some track acquisition time stored in the dynamic road segment database falls into the time zone, find the trajectory corresponding to the acquisition time, and then find out The road segments where the corresponding trajectories are located are then spliced out of the road plans by using the road segments; the cloud platform calculates the corresponding path plans according to the requirements of the cloud platform or the mobile terminal by using the qualified road segments.
- 根据权利要求1所述的方法,其特征在于,所述计算出对应的路径规划具体包括:The method according to claim 1, wherein the calculating the corresponding path plan specifically comprises:云平台将多个移动终端上传的某路段上的轨迹的数量计算出来,存储到云平台的数据库中,并与对应路段相关联;当云平台或移动终端设定一个轨迹数量阈值或轨迹数量比值阈值,并提出请求:当一些路段上的轨迹的数量落入这个所述轨迹数量阈值时,或当一些路段上的轨迹的数量与相关轨迹的数量的比值落入这个所述轨迹数量比值阈值时,找出所述一些路段,然后用所述一些路段拼接出一个路径规划;云平台则根据云平台或移动终端的请求用符合条件的所述一些路段,拼接出对应路径规划。The cloud platform calculates the number of tracks on a certain road segment uploaded by multiple mobile terminals, stores them in the database of the cloud platform, and associates them with the corresponding road segments; when the cloud platform or the mobile terminal sets a threshold number of tracks or a ratio of the number of tracks Threshold and request: when the number of trajectories on some road segments falls within the threshold of the number of trajectories, or when the ratio of the number of trajectories on some road segments to the number of related trajectories falls within the threshold of the number of trajectories And finding a part of the road segment, and then splicing a path plan with the some road segments; the cloud platform splicing out the corresponding path plan according to the request of the cloud platform or the mobile terminal by using the qualified road segments.
- 根据权利要求1所述的方法,其特征在于,所述更新和完善云平台内部的动态路段数据库还包括:The method according to claim 1, wherein the updating and improving the dynamic link database inside the cloud platform further comprises:通过检验在未知道路或原有道路上某一时间区域、某一些指定路段上的连续轨迹数量或相对数量,模拟生成允许转弯、禁止转弯交通限制信息,允许掉头、禁止掉头交通限制信息或只准单向行驶交通限制信息。By testing the number or relative quantity of continuous trajectories on a certain time zone or some specified road section on an unknown road or original road, simulating the generation of information that allows turning, prohibiting turning traffic restrictions, allowing U-turns, prohibiting U-turn traffic restrictions, or only One-way traffic restriction information.
- 根据权利要求6所述的方法,其特征在于,所述模拟生成允许转弯或禁止转弯交通限制信息包括:The method according to claim 6, wherein the simulating the generation of turning or prohibiting turning traffic restriction information comprises:云平台检验两个相交的路段是否共同拥有同一移动终端形成的连续的某转弯方向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的数量、或者同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照所述某转弯方向允许转弯的交通限制信息,存储到一个特殊的数据库中;反之,当这个计算结果小于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照所述某转弯方向禁止转弯的交通限制信息,存储到一个特殊的数据库中.The cloud platform checks whether two intersecting road segments share a continuous trajectory of a certain turning direction formed by the same mobile terminal, and calculates the number of such trajectories in a set time region, or the relative comparison with the related trajectories. Quantity, when the calculation result is greater than a preset value, the simulation generates traffic restriction information between the two road sections that is allowed to turn according to the turning direction at the intersecting node, and stores the information in a special database. Conversely, when the result of the calculation is less than a predetermined value, the simulation generates traffic restriction information between the two links that is prohibited from turning at the intersecting node according to the direction of the turn, and stores it in a special database. in.
- 根据权利要求6所述的方法,其特征在于,所述模拟生成允许掉头或禁止掉头交通限制信息包括:The method according to claim 6, wherein the simulation generation of the allowable U-turn or the U-turn traffic restriction information comprises:云平台检验某一个路段是否存在以某形值点为转折点的同一移动终端连续形成的正向和反向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的数量,或者,同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这个路段之间的允许在这个转折点按照所述轨迹转折方向掉头的交通限制信息,存储到一个特殊的数据库中;反之,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段之间的禁止在这个转折点按照所述轨迹转折方向掉头的交通 限制信息,存储到一个特殊的数据库中。The cloud platform checks whether a certain road segment has forward and reverse trajectories continuously formed by the same mobile terminal with a shape point as a turning point, and calculates the number of such trajectories in a set time region, or The relative quantity compared with the relevant trajectory. When the calculation result is greater than a preset value, the simulation generates traffic restriction information between the road segments that allows the U-turn in the turning direction of the turning point to be stored in a special In the database; otherwise, when the result of the calculation is less than a predetermined value, the simulation generates a traffic between the road segments that is prohibited from turning around at the turning point according to the direction of the turning point. Restrict information and store it in a special database.
- 根据权利要求6所述的方法,其特征在于,所述模拟生成只准单向行驶交通限制信息包括:The method according to claim 6, wherein the simulation generates only one-way traffic restriction information including:云平台检验某个的路段某个指定方向的移动终端形成的轨迹数量,并计算在一个设定的时间区域内这类所述轨迹的数量,或者,同相反方向的或其他相关的轨迹相比较的相对数量,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段在这个所述某个指定方向的禁止通行的交通限制信息,存储到一个特殊的数据库中。The cloud platform checks the number of tracks formed by a mobile terminal in a specified direction of a certain road segment, and calculates the number of such tracks in a set time region, or compares with the opposite direction or other related trajectories. The relative quantity, when the result of the calculation is less than a predetermined value, simulates the traffic restriction information of the prohibited passage of the road segment in the specified direction, and stores it in a special database.
- 根据权利要求1所述的方法,其特征在于,所述云平台根据所述更新和完善所述云平台内部的动态路段数据库的数据计算出相应的路径规划包括:The method according to claim 1, wherein the cloud platform calculates a corresponding path plan according to the data of updating and perfecting the dynamic link database inside the cloud platform, including:云平台先采用静态的常规的最短路径计算方法计算出n条总体距离最短的路径规划方案,再在所述n条总体距离最短的路径规划方案中根据所包括的路段上的即时动态阻抗计算出总体耗时最短的一条路径规划,所述路段包括:原有道路和未知道路上的路段。The cloud platform first calculates a path planning scheme with the shortest overall distance by using a static conventional shortest path calculation method, and then calculates the instantaneous dynamic impedance on the included road segment in the path planning scheme with the shortest overall distance of the n. A path plan with the shortest overall time consumption, the road segments include: original roads and road sections on unknown roads.
- 根据权利要求10所述的方法,其特征在于,所述静态的常规的最短路径计算方法,是指A*启发式搜索算法;并且所述A*启发式搜索算法,是用来根据所述更新和完善了的云平台内部的动态路段数据库数据计算出n条总体距离最短的路径规划方案的;所述A*启发式搜索算法,包括下限为0的A*启发式搜索算法的一种特例:dijkstra算法。The method according to claim 10, wherein said static conventional shortest path calculation method refers to an A * heuristic search algorithm; and said A * heuristic search algorithm is used to update according to said And the dynamic road segment database data inside the perfect cloud platform calculates the path planning scheme with the shortest overall distance n; the A * heuristic search algorithm includes a special case of the A * heuristic search algorithm with a lower limit of 0: Dijkstra algorithm.
- 根据权利要求1所述的方法,其特征在于,所述更新和完善云平台内部的动态路段数据库,是指将生成和更新后的所述未知道路上的路段数据,同原有路段数据一起存储在一个以邻接表方式表达的数据库中。The method according to claim 1, wherein the updating and improving the dynamic road segment database inside the cloud platform means storing the updated road segment data on the unknown road together with the original road segment data. In a database expressed in an adjacency list.
- 根据权利要求1所述的方法,其特征在于,所述云平台根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出和所述某一有特定要求的路径规划请求相对应的路径规划,具体包括:The method according to claim 1, wherein the cloud platform calculates a path planning request corresponding to the specific requirement according to the dynamic road segment database data inside the updated and improved cloud platform. Path planning, including:将轨迹信息中每一位置点的高程加权平均值或二维、三维运动方向数据的加权平均值、或视频照片同所在路段相关联存储在数据库中,用以区分近似路段;当云平台检索到包括高架桥上下高度不同但水平面位置相近或相同的、或其它高度相同但水平位置接近的一些所述近似路段时,再进一步定量比较所述近似路段结点的经纬度坐标,当两个路段对应结点的经度坐标值之差和纬度坐标值之差的绝对值同时小于一个设定的值时,则提取行驶在所述两个路段上面的移动终端的包括平均高程、平均行驶方向、视频、照片的轨迹信息;或同时计算所述两个路段与各自的前后相邻路段的衔接关系,并进行标记和提示,存储在一个特殊的动态路段数据库中;当移动终端提出某一有特定要求的路径规划请求时,云平台用存储在所述特殊的动态路段数据库中的包括所述平均高程、平均行驶方向、视频、照片的轨迹信息或衔接关系在内的数据,计算出相应的路径规划;然后将所述平均高程、平均行驶方向、视频、照片的轨迹信息或所述衔接关系连同标记和提示,同计算出的路径规划方案一起,发送给移动终端;所述计算衔接关系,是指累加某个路段上的每一个移动终端在直行或转弯过程中跨越结点行驶到相邻的路段时形成的连续轨迹的所得到的数量,当这个所述数量的值、或所述数量同其他相关轨迹数量相比的相对值,在一设定的时间区域内大于一个设定的值时,则确认为这两个路段以所跨越的结点为衔接点、在这个轨迹运行的方向上有衔接关系。 The elevation weighted average value of each position point in the trajectory information or the weighted average of the two-dimensional, three-dimensional motion direction data, or the video photograph is stored in the database in association with the road segment to distinguish the approximate road segment; when the cloud platform retrieves When the upper and lower heights of the viaduct are different but the horizontal planes are similar or identical, or some of the similar sections are similar in height but close to the horizontal position, the latitude and longitude coordinates of the approximate road segment nodes are further quantitatively compared, and when the two road segments correspond to the nodes When the absolute value of the difference between the longitude coordinate value and the latitude coordinate value is less than a set value at the same time, the mobile terminal traveling on the two road segments is extracted including the average elevation, the average traveling direction, the video, and the photo. Trajectory information; or simultaneously calculate the connection relationship between the two road segments and their respective adjacent road segments, and mark and prompt, store in a special dynamic road segment database; when the mobile terminal proposes a specific path planning When requested, the cloud platform uses the inclusions stored in the special dynamic road segment database. The average elevation, the average driving direction, the video, the trajectory information of the photo or the connection relationship, calculate the corresponding path planning; then the average elevation, the average driving direction, the video, the trajectory information of the photo or the connection relationship Together with the marked and prompted, the calculated path planning scheme is sent to the mobile terminal; the calculating the connection relationship refers to accumulating each mobile terminal on a certain road segment to travel adjacent to the node in a straight line or a turn. The resulting number of consecutive trajectories formed when the road segment, when the value of the quantity, or the relative value of the quantity compared to the number of other related trajectories, is greater than a set value in a set time zone At the time, it is confirmed that the two sections are connected by the nodes that are crossed, and have a connection relationship in the direction in which the trajectory runs.
- 根据权利要求1所述的方法,其特征在于,所述计算出对应的路径规划具体包括:云平台根据多个移动终端动态的实时上传的终端已有实时路径规划方案,及所涉及到的路段的即时动态阻抗,计算出未来某一指定时间某一指定路段上的移动终端的一个预测数量,然后根据所述预测数量找出云平台中存储的与所述预测数量相对应的该路段上的一些即时动态阻抗,将所述一些即时动态阻抗加权平均所得到的数值即为所述未来某一指定时间某一指定路段的预测动态阻抗,将所述预测动态阻抗与所述未来某一指定时间一起存储到云平台的动态路段数据库中;当一个移动终端提出某一特定的路径规划时,云平台根据所述预测动态阻抗,预测所述未来某一指定时间某一指定路段的交通拥堵状况,并将所述预测动态阻抗作为参量之一计算出一个对应路径规划方案,发送给移动终端。The method according to claim 1, wherein the calculating the corresponding path plan comprises: the real-time path planning scheme of the terminal that is dynamically uploaded by the cloud platform according to the dynamics of the plurality of mobile terminals, and the related road segment Instant dynamic impedance, calculating a predicted number of mobile terminals on a specified road segment at a specified time in the future, and then finding out the segment on the road segment corresponding to the predicted number stored in the cloud platform according to the predicted quantity Some instantaneous dynamic impedance, the value obtained by weighting the instantaneous dynamic impedances is the predicted dynamic impedance of a specified road segment at a specified time in the future, and the predicted dynamic impedance and the specified time in the future. Stored together in a dynamic road segment database of the cloud platform; when a mobile terminal proposes a specific path plan, the cloud platform predicts a traffic congestion condition of a specified road segment at a specified time in the future according to the predicted dynamic impedance. And calculating the predicted dynamic impedance as one of the parameters to calculate a corresponding path planning scheme, Send to the mobile terminal.
- 一种云平台,所述云平台包括多个智能设备,所述智能设备包括:处理器、存储器、通信接口和总线;其特征在于,A cloud platform, the cloud platform includes a plurality of smart devices, the smart device includes: a processor, a memory, a communication interface, and a bus;所述通信接口实时无线接收多个移动终端上传的多个轨迹信息或多个终端已有实时路径规划方案,处理器然后利用所述多个轨迹信息或多个终端已有实时路径规划方案,更新和完善云平台内部的动态路段数据库;当通信接口接收到移动终端提出的某一有特定要求的路径规划请求时,处理器根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出对应的路径规划,然后将所述对应的路径规划以无线方式发送给移动终端;The communication interface wirelessly receives multiple track information uploaded by multiple mobile terminals or multiple real-time path planning schemes of multiple terminals in real time, and the processor then uses the multiple track information or multiple terminals to have an existing real-time path planning scheme to update And perfecting the dynamic link database inside the cloud platform; when the communication interface receives a path planning request with specific requirements proposed by the mobile terminal, the processor calculates the dynamic road segment database data according to the updated and improved cloud platform. Corresponding path planning, and then transmitting the corresponding path plan to the mobile terminal in a wireless manner;所述轨迹信息包括:轨迹的数量及轨迹的获取时间,轨迹各点的经纬度及获取时间、高程及获取时间、二维或三维速度及获取时间、二维或三维运动方向及获取时间、视频或照片图像及获取时间,轨迹所属移动终端的代码;The trajectory information includes: the number of trajectories and the acquisition time of the trajectory, the latitude and longitude of the trajectory and the acquisition time, the elevation and acquisition time, the two-dimensional or three-dimensional velocity and acquisition time, the two-dimensional or three-dimensional motion direction and the acquisition time, video or Photo image and acquisition time, the code of the mobile terminal to which the track belongs;所述终端已有实时路径规划方案是指移动终端内部已有的且正在使用的、从所述移动终端本次上传开始时的所在地到目的地的一个路径规划方案;The real-time path planning scheme of the terminal refers to a path planning scheme existing and in use within the mobile terminal from the location to the destination when the mobile terminal starts the current uploading;所述更新和完善云平台内部的动态路段数据库,是指根据包括轨迹的数量及轨迹的获取时间在内的轨迹信息,生成和更新未知道路上的路段数据、生成和更新所有路段的即时动态阻抗,生成和更新所有路段的模拟交通限制信息,另外,根据所述多个终端已有实时路径规划方案和轨迹历史数据,生成和更新所有路段的预测动态阻抗;The updating and perfecting the dynamic road segment database inside the cloud platform refers to generating and updating road segment data on an unknown road, generating and updating real-time dynamic impedance of all road segments according to the trajectory information including the number of trajectories and the acquisition time of the trajectory. Generating and updating simulated traffic restriction information of all road segments, and generating and updating predicted dynamic impedances of all road segments according to the existing real-time path planning scheme and trajectory historical data of the plurality of terminals;所述所有路段是指包括新生成的路段和原有路段;所述轨迹的获取时间,是指构成轨迹各点的经纬度的获取时间所组成的一个和各点对应的时间集合;所述轨迹各点的经纬度的获取时间,是指移动终端在获取到所述各点的经纬度坐标时所处的时刻。The all the road segments are included in the newly generated road segment and the original road segment; the acquisition time of the trajectory refers to a time set corresponding to the acquisition time of the latitude and longitude constituting each point of the trajectory; The acquisition time of the latitude and longitude of the point refers to the time when the mobile terminal acquires the latitude and longitude coordinates of the points.
- 根据权利要求15所述的云平台,其特征在于,A cloud platform according to claim 15, wherein所述处理器具体用于,当移动终端在未知道路上行驶并上传轨迹信息时,所述处理器将所述轨迹信息中的位置信息,去除噪声及异常点并按照一定方法整理合并成一条或多条模拟道路,暂存到动态路段数据库中,同时累加所述模拟道路中的轨迹数量;当在某一设定的时间区域内,合并在某条所述模拟道路上的累加的所述轨迹数量落入某一设定阈值时,所述处理器将所述某条所述模拟道路转变成一条或几条新的临时或永久的新生成路段数据,存储到动态路段数据库中,然后所述处理器根据实时上传的新的轨迹信息对所述新生成路段及相关数据不断更新; The processor is specifically configured to: when the mobile terminal travels on an unknown road and uploads the track information, the processor removes the noise and the abnormal point from the position information in the track information, and merges and merges into one or a plurality of simulated roads, temporarily stored in the dynamic road segment database, and accumulating the number of tracks in the simulated road; and merging the accumulated tracks on a certain simulated road within a certain time zone When the quantity falls within a certain set threshold, the processor converts the certain simulated road into one or several new temporary or permanent newly generated road segment data, stores the data into a dynamic road segment database, and then the The processor continuously updates the newly generated road segment and related data according to the new trajectory information uploaded in real time;所述未知道路是指原有的所述动态路段数据库中没有对应数据的道路。The unknown road refers to a road in the original dynamic road segment database that does not have corresponding data.
- 根据权利要求15所述的云平台,其特征在于,A cloud platform according to claim 15, wherein所述处理器具体用于根据多个移动终端实时上传的轨迹的数量及轨迹的获取时间,计算出某一路段上某一时间区域的轨迹的平均耗时,并把所述的平均耗时作为一个即时动态阻抗存储在一个数据库中,所述某一路段是指原有道路上的路段或未知道路上新生成的路段;The processor is specifically configured to calculate an average time consuming of a trajectory of a certain time zone on a certain road segment according to the number of trajectories uploaded by a plurality of mobile terminals in real time and the acquisition time of the trajectory, and use the average time consuming time as An instantaneous dynamic impedance is stored in a database, and the certain road segment refers to a road segment on the original road or a newly generated road segment on the unknown road;当移动终端提出的某一特定要求的路径规划请求为:最短时间的路径规划请求时,所述处理器根据所述更新和完善了的云平台内部的动态路段数据库数据,计算出对应的路径规划具体包括:所述处理器用包含了这些即时动态阻抗的数据库数据,计算出总体耗时最短的路径规划。When the path planning request of a specific requirement proposed by the mobile terminal is: the shortest time path planning request, the processor calculates a corresponding path plan according to the dynamic road segment database data inside the updated and improved cloud platform. Specifically, the processor calculates the overall shortest path planning by using database data including these instantaneous dynamic impedances.
- 根据权利要求15所述的云平台,其特征在于,A cloud platform according to claim 15, wherein所述处理器将包括在原有道路和未知道路上行驶的多个移动终端上传的轨迹的获取时间存储到云平台的动态数据库中,并将所述轨迹的获取时间与对应轨迹所在的路段相关联;当云平台或移动终端设定一时间区域,并提出请求:当一些存储在所述动态数据库中的轨迹获取时间落入所述时间区域时,找出这些获取时间所对应的轨迹,再找出所述对应的轨迹所在的路段,然后用这些路段拼接出一个路径规划;所述处理器则根据云平台或移动终端的请求用符合条件的路段,计算出对应路径规划。The processor stores the acquisition time of the trajectory uploaded by the plurality of mobile terminals that are driven on the original road and the unknown road into a dynamic database of the cloud platform, and associates the acquisition time of the trajectory with the road segment where the corresponding trajectory is located When the cloud platform or the mobile terminal sets a time zone, and makes a request: when some track acquisition time stored in the dynamic database falls into the time zone, find the trajectory corresponding to the acquisition time, and then find The road segments where the corresponding trajectories are located are used, and then a path plan is spliced by using the road segments; the processor calculates the corresponding path plan according to the requirements of the cloud platform or the mobile terminal by using the qualified road segments.
- 根据权利要求15所述的云平台,其特征在于,A cloud platform according to claim 15, wherein所述处理器将多个移动终端上传的某路段上的轨迹的数量计算出来,并存储到云平台的数据库中,同时与所述轨迹所在的路段相关联;当云平台或移动终端设定一个轨迹数量阈值或轨迹数量比值阈值,并提出请求:当一些路段上的轨迹的数量落入这个所述轨迹数量阈值时,或当一些路段上的轨迹的数量与相关轨迹的数量的比值落入这个所述轨迹数量比值阈值时,找出所述一些路段,然后用所述一些路段拼接出一个路径规划;所述处理器则根据云平台或移动终端的请求用符合条件的所述一些路段,拼接出对应路径规划。The processor calculates the number of tracks on a certain road segment uploaded by the plurality of mobile terminals, and stores them in a database of the cloud platform, and is associated with the road segment where the track is located; when the cloud platform or the mobile terminal sets one The number of trajectories threshold or the number of trajectory ratio thresholds, and requests: when the number of trajectories on some road segments falls within the threshold number of the trajectories, or when the ratio of the number of trajectories on some road segments to the number of related trajectories falls into this When the number of trajectory ratio thresholds is found, the some road segments are found, and then a path plan is spliced by using the road segments; and the processor splices the segments according to the requirements of the cloud platform or the mobile terminal. Corresponding path planning.
- 根据权利要求15所述的云平台,其特征在于,A cloud platform according to claim 15, wherein所述处理器具体用于通过检验在未知道路或原有道路上某一时间区域、某一些指定路段上的连续轨迹数量或相对数量,模拟生成允许转弯、禁止转弯交通限制信息,允许掉头、禁止掉头交通限制信息或只准单向行驶交通限制信息。The processor is specifically configured to simulate to generate turning and prohibiting turning traffic restriction information by verifying the number or relative number of continuous tracks on a certain time zone or a certain time zone on an unknown road or an original road, allowing for U-turn and prohibition U-turn traffic restriction information or only one-way traffic restriction information.
- 根据权利要求20所述的云平台,其特征在于:The cloud platform of claim 20, wherein:所述处理器具体用于检验两个相交的路段是否共同拥有连续的同一移动终端形成的某转弯方向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的数量、或者同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照所述某转弯方向允许转弯的交通限制信息,存储到一个特殊的数据库中;反之,当这个计算结果小于一个事先设定的值时,则模拟生成这两个路段之间的在相交的结点按照所述某转弯方向禁止转弯的交通限制信息,存储到一个特殊的数据库中。The processor is specifically configured to check whether two intersecting road segments have a trajectory of a certain turning direction formed by consecutive same mobile terminals, and calculate the number, or the correlation, of the trajectories in a set time zone. The relative quantity of the trajectories compared, when the calculation result is greater than a predetermined value, the simulation generates traffic restriction information between the two road sections that is allowed to turn according to the certain turning direction at the intersecting node, and stores In a special database; otherwise, when the result of the calculation is less than a predetermined value, the simulation generates traffic restriction information between the two road segments at which the intersecting nodes prohibit turning according to the direction of the turn, and stores Go to a special database.
- 根据权利要求20所述的云平台,其特征在于:The cloud platform of claim 20, wherein:所述处理器具体用于检验某一个路段是否存在以某形值点为转折点的同一移动终端连续形成的 正向和反向的轨迹,并计算在一个设定的时间区域内这类所述轨迹的数量,或者,同相关轨迹相比较的相对数量,当这个计算结果大于一个事先设定的值时,则模拟生成这个路段之间的在这个转折点按照所述轨迹转折方向允许掉头的交通限制信息,存储到一个特殊的数据库中;反之,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段之间的在这个转折点按照所述轨迹转折方向禁止掉头的交通限制信息,存储到一个特殊的数据库中。The processor is specifically configured to check whether a certain road segment is continuously formed by the same mobile terminal with a shape point as a turning point. The forward and reverse trajectories, and calculate the number of such trajectories in a set time region, or the relative amount compared with the relevant trajectory, when the calculation result is greater than a predetermined value, Then, the simulation generates a traffic restriction information between the road segments that allows the U-turn in the turning direction of the turning point to be stored in a special database; otherwise, when the calculation result is less than a preset value, the simulation generates The traffic restriction information between the road sections that prohibits the U-turn at the turning point according to the direction of the turning of the track is stored in a special database.
- 根据权利要求20所述的云平台,其特征在于:The cloud platform of claim 20, wherein:所述处理器具体用于检验某个的路段某个指定方向的移动终端形成的轨迹数量,并计算在一个设定的时间区域内这类所述轨迹的数量,或者,同相反方向的或其他相关的轨迹相比较的相对数量,当这个计算结果小于一个事先设定的值时,则模拟生成这个路段在这个所述某个指定方向的禁止通行的交通限制信息,存储到一个特殊的数据库中。The processor is specifically configured to check the number of tracks formed by a mobile terminal in a specified direction of a certain road segment, and calculate the number of such tracks in a set time region, or the same direction or other The relative number of correlation trajectories is compared. When the calculation result is less than a preset value, the traffic restriction information of the prohibited passage of the road segment in the specified direction is generated and stored in a special database. .
- 根据权利要求15所述的云平台,其特征在于:The cloud platform of claim 15 wherein:所述处理器具体用于先采用静态的常规的最短路径计算方法计算出n条总体距离最短的路径规划方案,再在n条最短路径规划方案中根据所包括路段上的即时动态阻抗计算出总体耗时最短的一条路径规划,所述路段包括:原有道路和未知道路上的路段。The processor is specifically configured to calculate a path planning scheme with the shortest overall distance by using a static conventional shortest path calculation method, and then calculate an overall size according to the instantaneous dynamic impedance on the included road segment in the n shortest path planning schemes. The shortest path planning, including the original road and the road section on the unknown road.
- 根据权利要求24所述的云平台,其特征在于:A cloud platform according to claim 24, wherein:所述静态的常规的最短路径计算方法,是指A*启发式搜索算法;并且所述A*启发式搜索算法是用来根据所述更新和完善了的云平台内部的动态路段数据库数据计算出n条总体距离最短的路径规划方案的;所述A*启发式搜索算法,包括下限为0的A*启发式搜索算法的一种特例:dijkstra算法。The static conventional shortest path calculation method refers to an A * heuristic search algorithm; and the A * heuristic search algorithm is used to calculate the dynamic link database data based on the updated and improved cloud platform. n The overall shortest path planning scheme; the A * heuristic search algorithm, including a special case of the A * heuristic search algorithm with a lower bound of 0: the dijkstra algorithm.
- 根据权利要求15所述的云平台,其特征在于:The cloud platform of claim 15 wherein:所述更新和完善云平台内部的动态路段数据库,是指将生成和更新后的所述未知道路上的路段数据,同原有路段数据一起存储在一个以邻接表方式表达的数据库中。The updating and perfecting the dynamic road segment database inside the cloud platform means that the road segment data on the unknown road generated and updated is stored together with the original road segment data in a database expressed in an adjacency list manner.
- 根据权利要求15的云平台,其特征在于:A cloud platform according to claim 15 wherein:所述处理器具体用于将轨迹信息中每一位置点的高程加权平均值或二维、三维运动方向数据的加权平均值、或视频照片同所在路段相关联存储在数据库中,用以区分近似路段;当云平台检索到包括高架桥上下高度不同但水平面位置相近或相同的、或其它高度相同但水平位置接近的一些所述近似路段时,再进一步定量比较所述近似路段结点的经纬度坐标,当两个路段对应结点的经度坐标值之差和纬度坐标值之差的绝对值同时小于一个设定的值时,则提取行驶在所述两个路段上面的移动终端的包括平均高程、平均行驶方向、视频、照片的轨迹信息;或同时计算所述两个路段与各自的前后相邻路段的衔接关系,并进行标记和提示,存储在一个特殊的动态路段数据库中;当移动终端提出某一有特定要求的路径规划请求时,云平台用存储在所述特殊的动态路段数据库中的包括所述平均高程、平均行驶方向、视频、照片的轨迹信息或衔接关系在内的数据,计算出相应的路径规划;然后将所述平均高程、平均行驶方向、视频、照片的轨迹信息或所述衔接关系连同标记和提示,同计算出的路径规划方案一起,发送给移动终端;所述计算衔接关系,是指累加在某个路段上的某一指定方向上每一个移动终端在直行或转弯过程中跨越结点行驶到相邻的路段时形成的连续轨迹所得到的数量,当这个所述数量的值、或所述数量与相关轨迹数量相比较的相对值落入一个设定的阈 值时,则确认为这两个路段以所跨越的结点为衔接点、在这个轨迹运行的方向上有衔接关系。The processor is specifically configured to store an elevation weighted average value of each position point in the track information or a weighted average of the two-dimensional and three-dimensional motion direction data, or a video photo in a database in association with the road segment, to distinguish the approximation a road section; when the cloud platform retrieves some of the approximate road sections including the heights of the viaducts at different heights but the water level positions are similar or the same, or other heights are the same but the horizontal positions are close, the latitude and longitude coordinates of the approximate road section nodes are further quantitatively compared. When the absolute value of the difference between the longitude coordinate values of the corresponding nodes of the two road segments and the latitude coordinate values is simultaneously less than a set value, the average elevation and average of the mobile terminals traveling over the two road segments are extracted. Trajectory information of driving direction, video, and photo; or simultaneously calculating the connection relationship between the two road segments and their respective adjacent road segments, and marking and prompting, storing in a special dynamic road segment database; when the mobile terminal proposes a certain The cloud platform is stored in the special dynamic path when there is a specific path planning request The data in the database including the average elevation, the average driving direction, the video, the trajectory information of the photo or the connection relationship, and the corresponding path planning is calculated; then the average elevation, the average driving direction, the video, and the trajectory of the photo are calculated. The information or the connection relationship together with the mark and the prompt are sent to the mobile terminal together with the calculated path planning solution; the calculating the connection relationship means that each mobile terminal is accumulated in a certain direction on a certain road segment. The number of continuous trajectories formed when traveling across a node to an adjacent road segment during straight or cornering, when the value of the quantity, or the relative value of the quantity compared with the number of related trajectories falls within a setting Threshold When the value is obtained, it is confirmed that the two road segments have the junction point as the junction point and the connection direction in the direction in which the trajectory runs.
- 根据权利要求15所述的云平台,其特征在于:The cloud platform of claim 15 wherein:所述计算出对应的路径规划,是指云平台根据多个移动终端实时上传的终端已有实时路径规划方案,及所涉及到的路段的一段时间范围内的即时动态阻抗,计算出未来某指定时间某指定路段上的移动终端的一个预测数量,然后根据所述预测数量找出云平台中存储的与所述预测数量相对应的该路段的一些即时动态阻抗,将所述一些即时动态阻抗加权平均所得到的数值即为所述未来某指定时间某指定路段上的预测动态阻抗,然后将所述预测动态阻抗与对应时间一起存储到云平台的动态路段数据库中;当一个移动终端提出某一特定的路径规划时,云平台根据所述预测动态阻抗,预测未来某指定时间、某指定路段的交通拥堵状况,并将所述预测动态阻抗作为参量之一,同时根据云平台中的其他轨迹信息计算出一个对应的路径规划。 The calculation of the corresponding path plan refers to the existing real-time path planning scheme of the terminal uploaded by the cloud platform according to the real-time upload of the mobile terminal, and the instantaneous dynamic impedance within a certain period of time of the involved road segment, and calculating a future designation. a predicted quantity of the mobile terminal on a specified road segment, and then, according to the predicted quantity, find some instantaneous dynamic impedance of the road segment stored in the cloud platform corresponding to the predicted quantity, and weight the some instantaneous dynamic impedance The average obtained value is the predicted dynamic impedance on a specified road segment at a specified time in the future, and then the predicted dynamic impedance is stored together with the corresponding time in the dynamic road segment database of the cloud platform; when a mobile terminal proposes a certain During a specific path planning, the cloud platform predicts a traffic congestion condition at a specified time and a specified road segment according to the predicted dynamic impedance, and uses the predicted dynamic impedance as one of the parameters, and according to other trajectory information in the cloud platform. Calculate a corresponding path plan.
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