EP4323725A1 - Method and system for determining a starting point between two entities - Google Patents

Abstract

The invention relates to a method for determining a starting point (M) between two entities (E₁, E₂), wherein the entities (E₁, E₂) are each configured to determine their location (A, B) and to communicate by means of a communication interface. The invention is characterized in that the locations (A, B) of the entities (E₁, E₂) are determined in map material (1), a route (3), composed of at least two route points (2) each connected by means of a route section (P₁, P₂, P₃, P₄, P₅, P₆), between the two locations (A, B) of the entities (E₁, E₂) is determined in the map material (1), and, in order to iteratively determine a position of the starting point (M) on the route (3), the route sections (P₁, P₂, P₃, P₄, P₅) included in the route (3) are subdivided into route subsections (P₃₁, P₃₂, P₃₃, P₃₄, P₃₅), with the result that a section of the route (3) extending from the location (A, B) of a first entity (E₁, E₂) to the starting point (M) can be covered in the same time and/or has the same length as a section of the route (3) extending from the location (A, B) of a second entity (E₁, E₂) to the starting point (M), wherein an entity (E₁, E₂) moves, with a means of transport assigned thereto, along the route (3) in each case.

Description

Method and system for determining an origin between two entities

The invention relates to a method for determining a starting point between two entities according to the type defined in more detail in the preamble of claim 1 and a system for determining the starting point.

Often two entities, such as people, want to meet in one place, for example to have a coffee or go for a walk. Furthermore, the daily business of a delivery service consists of delivering goods to different locations. For this purpose, the delivery service operates a means of transport that brings the goods from a starting point to, for example, two different delivery locations.

This raises the question of where exactly the two people should meet, or where the starting point for the delivery should be chosen, so that both people have about the same distance to the meeting point, or the two delivery locations can be reached equally quickly from the starting point. This ensures the fastest possible meeting at the meeting point or delivery of the goods. Furthermore, the journey of the two people to a meeting point that is in the middle of the places where the people are staying in terms of time and/or location is particularly fair, since no one person has to travel much longer than the other person.

The following can be understood as entities, for example: people, mobile end devices such as a smartphone, laptop, tablet computer, wearables or the like. A corresponding person or computing unit can also be assigned to a means of transport. Any road, rail, water or air vehicle can be used as a means of transport. The computing unit can also be integrated into the means of transport. KR 1020100049859 A discloses a search method and a search device for finding a rendezvous point, the rendezvous point corresponding to a midpoint between two entities meeting at the rendezvous point. In order to determine a suitable rendezvous point located approximately midway between the entities, points of interest (POIs) located near the midpoint are sought and examined for their suitability for the rendezvous. A distance between the two entities in map material is determined and this is halved to determine the center point.

The present invention is based on the object of specifying an improved method and system for determining such a starting point between two entities, with the aid of which a position of the starting point between the entities can be determined particularly fairly and precisely in different starting situations.

According to the invention, this object is achieved by a method for determining a starting point between two entities with the features of claim 1 and a corresponding system with the features of claim 10. Advantageous configurations and developments result from the dependent claims.

In a method for determining the origin between two entities, the two entities are able to determine their location and communicate via a communication interface. According to the invention, the whereabouts of the entities are determined in map material, a route composed of at least two route points each connected by a route section between the two whereabouts of the entities in the map material is determined, and for iteratively determining a position of the starting point on the route, the route sections covered by the route divided into sub-route sections, so that a route stretching from the whereabouts of a first entity to the starting point can be covered in the same time and/or has the same path length as a route stretching from the whereabouts of a second entity to the starting point, with each entity moves along the route with a means of transport assigned to it. The starting point between the entities can be determined particularly fairly with the aid of the method according to the invention, so both entities travel the same distance to reach the starting point and/or require the same amount of time to do so. An influence of a means of transport used by a respective entity on a journey duration or route is taken into account. For example, if the first entity travels in a car and the second entity travels in a bicycle, the distance to be traveled by the first entity may be greater than the distance to be traveled by the second entity, since the car typically travels faster than the bicycle. The distance to be covered by the car and the distance to be covered by the bicycle can be covered by the respective means of transport in the same period of time. The same time period or path length is to be understood as meaning the same time period or path length minus or plus a specified tolerance range.

By dividing the route between the original locations of the first and second entity into at least one route section, the starting point on the route can be positioned particularly precisely at an actual spatial and/or temporal midpoint on the route. Especially in the case of a complex route made up of a large number of different route sections, this ensures that the two entities actually have to travel the same distance and/or the time required for this to reach the starting point. A route section can be formed, for example, from a road section such as a straight road or a curve, with each route section being provided with parameters. These parameters include, for example, a distance of the route section, a time required to cover the route section at a driving speed that is typical for the means of transport, a speed limit that applies to the route section, or the like.

Analogously to the prior art, points of interest (POIs) located in the vicinity of the route can be taken into account for determining the position of the starting point. For example, the starting point can also be shifted closer in the direction of the first or second entity if there is a for the entities interesting destination such as a cafe, library, park or the like.

By dividing a route section into sub-route sections, a position of the starting point on the route can be found more precisely. It is therefore unlikely that the starting point will coincide with a route point or midpoint of a route section directly when dividing the route. By dividing the route section that includes the starting point into sub-route sections, the starting point can be placed at an end point or midpoint of a sub-route section, with the properties such as route length, travel time, speed limit and the like of the route section being divided accordingly. If the starting point does not coincide with an end or middle point of a sub-route section in a first iteration, i.e. is not within a tolerance range in the intended spatial and/or temporal center between the starting points of the entities, then in a further iteration of the Further subdivide the sub-route section that includes the starting point. A starting point located at the midpoint of a route section corresponds to a starting point located at an end point of a sub-route section.

To determine the whereabouts of an entity, it can have any location determining device, for example a receiver of a global navigation satellite system. In addition to its whereabouts, the entity can also transmit further information via the communication interface. The communication can take place directly between the entities or indirectly via a third processing unit. Any proven communication technology can be used as the communication technology. For example, the communication can take place wirelessly, in particular by means of mobile radio, WiFi, Bluetooth, NFC or the like.

The route is calculated and the starting point on the route is found either on a central processing unit and/or on at least one of the two entities. For this purpose, the two entities transmit their respective whereabouts to the central processing unit and/or the respective other entity by means of the communication interface. If the determined starting point is within a predetermined tolerance range, the two entities may have to agree to the determined position of the starting point and a width of the tolerance range before they start their journey to the starting point. This ensures that the starting point is not unfairly moved too close to one of the entities. With the help of the tolerance range, an arrival of an entity at the starting point at a later time than an agreed time, for example due to a delay due to traffic jams and/or a timetable deviation, can be compensated.

An advantageous development of the method provides that the first and second entities meet at the starting point, based on their respective whereabouts. As already mentioned, the starting point can be, for example, a cafe, a library, a park or the like, from which the two entities start a joint activity. In this example, the starting point could also be interpreted as a meeting point or rendezvous point.

According to a further advantageous embodiment of the method, at least one third entity travels from the starting point along the route extending from the location of the first entity to the starting point to the location of the first entity and at least one fourth entity travels from the starting point along the route from the location of the second entity to the starting point reaching distance to the whereabouts of the second entity.

The method according to the invention can thus also be used to optimize a route to be covered by a means of transport of a delivery service or the time required for this. A delivery service can send a distribution vehicle to the starting point, the distribution vehicle including drones, in particular autonomously controlled drones, which then swarm out along the respective route to the whereabouts of the first and second entity. Since this preferably requires the same amount of time to cover the route to reach the first and second entity, it is made possible for the drones to arrive at the distribution vehicle again at the same time, even after goods to be delivered have been handed over, in a particularly reliable manner. As a result, efficiency for distributing goods for the delivery service can be improved. It is also possible for people to travel with the distribution vehicle, who then travel from the starting point, for example, with the same or a different means of transport to the whereabouts of the first and second entity. The delivery service can be, for example, a parcel deliverer, a food delivery service or the like. In addition to POIs such as an optimal parking position for the distribution vehicle, other map information can also be read from the map material, for example a no-fly zone for unmanned drones.

A further advantageous embodiment of the method also provides that the whereabouts of the entities are determined in map material provided by at least two map providers, with the whereabouts of one entity determined in the different map material being compared with one another. By using map material provided by various map providers, the whereabouts of a respective entity and ultimately also the position of the starting point on the route can be determined even more precisely. By comparing map data from different providers, position deviations or an inaccurately determined position of an entity can be identified and corrected. The map material from the different map providers can also include different POIs and/or map information. This increases the amount of information used to carry out the method according to the invention. As a result, the method can be used even more reliably.

According to a further advantageous embodiment of the method, current traffic information is taken into account when calculating the route between the first and the second entity. If the first entity is traveling by car, for example, there may be a traffic jam on the route covered by the first entity. This lengthens a time required to cover the distance.

If, for example, the second entity travels by public transport such as a subway, tram, suburban train, city bus or the like, delays can also occur here. Information about possible traffic jams and/or timetable changes can be obtained from reliable third-party sources. These delays are advantageously taken into account when determining the starting position. For example, when a time required to travel a distance is lengthened by such a delay, the starting point becomes shifted in such a way that both entities still arrive at the starting point at the same time plus minus the specified tolerance threshold, or third and fourth entities swarming out from the starting point arrive at the location of the first and second entity at the same time. This ensures, even in realistic traffic situations, that a position of the starting point is determined particularly fairly and precisely.

A further advantageous embodiment of the method also provides that at least one entity moves along the route using one of the following means of transport: on foot; on a bike; on an e-scooter; by public transport, in particular by bus and/or train; with a car, in particular a car, truck and/or van; with an aircraft or with an autonomously controllable vehicle, in particular a drone, preferably a flying drone.

In general, it is also conceivable that the entity also changes the means of transport during its journey along the route. For example, the entity can walk during a first section of the route, then switch to a bicycle and cover a last section of the route, for example by bus. The entity can also use an e-scooter, for example. This enables the method according to the invention to be used in even more extensive and different travel situations.

For example, if both entities travel by train, stops in map material are determined for each entity within a specified radius around a location of the respective entity and connections originating from the respective stops, including potential transfer options to the respective stop near the other entity determined and examined for their travel time. Also used to determine the total travel time for an entity For example, a distance and/or length of time that the respective entity has to travel to the stop, for example on foot, is taken into account. A stop on the route between the whereabouts of the entities, which can be reached by the two entities at the same time and/or is the same distance away, is then determined as the starting point. The starting point can also be outside of a corresponding stop, for example a cafe in the vicinity of a corresponding stop. It is also conceivable that one entity travels by train and one entity travels exclusively on foot.

Similarly, one of the entities can travel by bicycle and one of the entities can walk. Average travel speeds for the respective entities are assumed to determine the starting point. The travel speeds of the respective entities can also be learned depending on the means of transport they have chosen. In this way, the travel behavior of a specific entity can be observed over a longer period of time, resulting in time- and/or distance-dependent locomotion speeds. For example, if the first entity travels a specific route at a specific time on a subway, a longer period of time may be necessary for this purpose, for example at rush hour due to the boarding and exiting of a large number of people. If the second entity travels by bicycle, for example, it may need a shorter or longer period of time to travel a certain route section, for example if the second entity has to ride uphill or downhill, or, for example, drives more slowly after lunch because of a full stomach.

According to a further advantageous embodiment of the method, an algorithm for determining the position of the starting point on the route carries out at least the following steps:

calculating the route between the locations of the two entities; halving the calculated route with respect to a travel length of the route or a time required to travel the route to determine a half distance; as long as a current distance starting from one of the locations is less than half the distance: adding the next subsequent route section to the current distance; as soon as the current distance is greater than half the distance: subdividing the last added route section into n sub-route sections; and as long as the current distance minus the last added route leg is less than half the distance: Add the next subsequent sub-route leg to the current distance.

By dividing the route into route sections or sub-route sections and by taking into account map material provided by different map providers, a position of the starting point can be found particularly precisely on a spatial and/or temporal midpoint between the two entities. The steps carried out by the algorithm for this purpose allow the algorithm to be carried out particularly quickly and efficiently. Route points on the route are determined to subdivide the route into the route sections. The route points correspond, for example, to a transition from a straight road to a curve or the like in the map material. In this way, the algorithm checks for each route section whether the middle point between the first and the second entity has been reached. If no exact center point can be found on a corresponding route section and/or a route point, then a corresponding route section is subdivided into sub-route sections. This ensures that the position of the starting point is found particularly centrally between the whereabouts of the first and second entity. Accordingly, when determining the route, the means of transport used by the respective entity is taken into account.

A further advantageous embodiment of the method also provides that the starting point is recalculated taking into account a current whereabouts of at least one of the entities. If, for example, there is a delay in at least one entity during the journey along the route, this would result in both entities not arriving at the starting point at the same time. Similarly, in the example of the delivery service, the goods would not arrive at the two entities at the same time and/or the drones delivering the goods would not return to the distribution vehicle at the same time. However, by monitoring the current position of each entity as it travels along the route, the position of the starting point along the route can be shifted adaptively. This means that the entities can arrive at the starting point or the Arrival of the goods at the original locations of the first and second entities are guaranteed. When the drones return to the distribution vehicle, the distribution vehicle can also move in the direction of a drone if this drone takes longer than expected to return.

At least one of the following criteria is preferably additionally taken into account for determining the position of the starting point on the route: fairness; a quantity of pollutants produced by moving at least one means of transport along the route, in particular a CC> ₂ quantity; an amount of energy required by at least one vehicle to move along the route; and/or costs incurred for moving at least one means of transport along the route.

By taking into account at least one of the criteria mentioned, a shift in the starting point on the route can be adjusted according to customer preferences. For example, according to a first scenario, the starting point can be positioned on the route in such a way that the first and second entities reach the starting point after as short a period of time as possible. For example, the first entity travels to the starting point by car, but the second entity has to change modes of transport several times to reach the starting point. This involves a lot of effort for the second entity. Considering fairness, the starting point can be shifted on the route such that it takes a longer time for the first and second entities to reach the starting point, but the first and second entities have to overcome a similar effort to reach the starting point. For example, the starting point can then be set at a public transport stop, whereupon both the first and second entities travel to the starting point by public transport. To do this, the first and second entity must then transfer equally often.

Acceptance of carrying out the method according to the invention can be increased by taking into account the amount of pollutants produced by environmentally conscious people. Correspondingly, an amount of energy required for traveling along the route and/or costs incurred as a result for positioning the starting point on the route can also be taken into account.

In particular, a customer is able to decide for himself which of the criteria mentioned should also be taken into account for determining the position of the starting point. This ensures a particularly high level of comfort and satisfaction when using the method according to the invention.

In a system for determining a starting point between two entities, comprising at least two entities, wherein the entities are each set up to determine their location and to share it via a communication interface, at least the two entities are set up according to the invention to carry out a method described above .

The entities are, for example, people or computing units, for example in the form of a mobile terminal device such as a smartphone, tablet computer, laptop, wearable or the like. The persons and/or computing units can travel with a means of transport such as a car, truck, van, bus, train, bicycle, on foot or the like. It is also possible to change the means of transport during a journey of an entity. At least one entity can also be integrated into a corresponding means of transport. For example, an entity can be formed by a computing unit of a vehicle.

The two entities can also communicate indirectly via a central processing unit. The central processing unit can also determine the starting point for the two entities. For this purpose, the central processing unit receives the whereabouts of the two entities and, using a method according to the invention, determines the starting point for the meeting or for the swarming of drones.

Further advantageous refinements of the method according to the invention for determining the starting point between the entities also result from Embodiments, which are described in more detail below with reference to the figures.

show:

1 shows a schematic representation of two entities meeting at a starting point on a digital road map;

FIG. 2 shows a schematic representation of a route divided into a plurality of route sections; FIG. and

3 shows a basic representation of a flow chart of a method according to the invention for determining the starting point between the entities.

FIG. 1 shows map material 1, here in the form of a digital road map. In the example in FIG. 1, the digital road map includes a section of a metropolitan area, for example a large city. In the big city there are two entities Ei and E at respective locations A and B. The two entities Ei and E have arranged to meet. A starting point M is determined with the aid of a method according to the invention, to which the two entities Ei and E can reach in the same time and/or by covering the same distance. The first entity Ei is located at an original location A and the second entity E at an original location B. The starting point M is located within a tolerance range 8 shown in Figure 2 in the middle between the two locations A and B.

The entities Ei and E are, for example, people or computing units, for example in the form of a mobile terminal such as a smartphone, tablet computer, laptop, wearable or the like. Such a computing unit can also be integrated into a vehicle. For example, the processing unit can then be a central on-board computer of a vehicle, a control unit of a vehicle subsystem, a telematics unit or the like.

The two entities Ei and E each move through the city with a means of transport. For example, the entities Ei and E are on foot, by bicycle, by e-scooter, by means of local public transport, a privately operated vehicle such as a car, truck, van or the like, and/or a autonomously operated vehicle, such as a drone, on the road. It is also possible to change the means of transport once or several times during a journey from an original place of residence A, B to the starting point M. For example, an entity Ei, E2 in the form of a person can drive from their place of residence with an e-scooter to a public transport stop and then travel by bus, for example, to a stop near the starting point M and walk from there from the stop reach the starting point M.

According to the invention, the starting point M is located in the middle between the locations A, B of the entities Ei, E2 with regard to a path length and/or a time period required to cover a distance between the starting point M and the respective locations A, B of the entities Ei _, E2. To determine a position of the starting point M between the entities Ei and E2, a different travel speed depending on a selected means of transport is taken into account.

To determine the starting point M, the entities Ei and E2 determine their respective whereabouts A, B. A route 3, which extends from whereabouts A of the first entity Ei to whereabouts B of the second entity E2, is then determined. The route 3 is halved to determine the starting point M with regard to its path length and/or the time required to cover the route 3 . While the two entities Ei and E2 travel to the starting point M, they move along route 3. In doing so, they can record their current whereabouts A* and B*. According to one embodiment of the method according to the invention, the respective current location A*, B* can be used for the adaptive displacement of the starting point M. For example, if one of the entities Ei, E2 is stuck in traffic, the starting point M can be shifted closer to the respective entity Ei, E2. This ensures that the two entities Ei and E2 arrive at the exit point M simultaneously as planned.

It is also possible for one or more POIs 6 to be located near the route 3 and for the starting point M to be placed on one of these POIs 6 or in close proximity thereto. For example, the POI 6 can be a cafe, a library, a park or the like. In other words, the two entities Ei and E2 are planning a meeting at one of the POIs 6. In order to improve the accuracy with which the respective whereabouts A, A*, B, B* are determined, map material 1 provided by different map providers can be used according to one embodiment of the method according to the invention.

The procedure for halving route 3 is explained in more detail with reference to FIG. Route 3 is thus composed of a large number of route sections Pi _, P ₂ , P ₃ , P ₄ , P ₅ , Rb. A route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb extends between two route points 2. For example, a route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb corresponds to a specific road section, for example a straight stretch of road, or a curve. The route points 2 are, for example, traffic lights, intersections, roundabouts or the like. By dividing the route 3 into the route sections Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb, the route 3 can be simulated particularly realistically and the starting point M can thus be placed particularly precisely in the middle between the two locations A and B.

Since it is to be expected that the starting point M does not necessarily coincide with a route point 2, a route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb, here in the example in Figure 2 the third route section P ₃ into n sub-route sections P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃₅ . This subdivision can be continued iteratively until the starting point M is in the middle of a sub-route section P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃₅ , on a route point 2 or an end point of a sub-route section P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃₅ . Each route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb has a corresponding path length or one for covering the respective route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb depending on a selected means of transport required time.

A starting point M placed “in the middle” between the whereabouts A and B of the entities Ei and E ₂ is understood if it is within a specified tolerance range 8 on a route section Pi, P ₂ , P ₃ , P ₄ , P ₅ , Rb or sub-route section P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃₅ is located. The illustration is not true to scale. According to one embodiment of the method according to the invention, it is also possible for a distribution vehicle 7, which is shown in FIG Swarm Entities Egg and E2. For example, the drones can deliver goods to the first and second entities Ei and E2. The goods can be packages or food, for example.

FIG. 3 shows a flow chart 300 of the method according to the invention. In an optional method step 301, the two entities Ei _, E2 can specify whether additional criteria should be taken into account when determining the starting point M. The additional criteria are, for example, fairness, an amount of pollutants caused by moving at least one means of transport along Route 3, in particular in the form of CO2, an amount of energy required by at least one means of transport to move along Route 3 and/or costs incurred for this .

In a method step 302, the two entities Ei and E2 arrange to meet at the starting point M. In the example in FIG. 3, the respective location A, B is transmitted to a central processing unit 5, for example a cloud server or a backend of a service provider. The starting point M is then determined by the central processing unit 5 . For this purpose, an algorithm 4 is executed on the central processing unit 5 . Algorithm 4 comprises six work steps 401, 402, 403, 404, 405 and 406. In work step 401, route 3 between locations A and B of the two entities Ei and E2 is determined. In step 402, route 3 is halved with regard to its path length and/or a time required to cover route 3. In step 403, a distance starting from one of the locations A, B is lengthened by adding route sections P2, P3, P4, P5. If, in step 404, the distance thus extended is greater than half the distance, the last added route section P3 is subtracted from the distance and this route section P3 is divided into n sub-route sections P31, P32, P33, P34, P35 in the example in Figure 2 five sub Route sections P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃₅ divided. In step 405, the sub-route sections P ₃₁ , P ₃₂ , P ₃₃ , P ₃₄ , P ₃ san are added to the distance until the distance is equal to or greater than half the distance. Finally, in step 406, the starting point M is found. This is then sent back to the two entities Ei and E ₂ so that they can begin their journey to the starting point M.

It is also possible for a location of the starting point M and/or other information linked thereto to be transmitted to a distribution vehicle 7 . The distribution vehicle 7 includes further entities, here in the form of a third, fourth, fifth and sixth entity E ₃ , E ₄ , Es, Es. These can be, for example, individual persons or also autonomous drones, for example airworthy drones, which deliver goods, meals or the like to the two entities Ei and E ₂ . If the distribution vehicle 7 is in the starting point M when the third and fourth entities E _ß and E ₄ swarm out from the distribution vehicle 7, the third and fourth entities E ₃ and E ₄ can reach the first and second entities Ei and E ₂ at the same time preferably arrive back at the distribution vehicle 7 at the same time. This enables a delivery service to distribute goods to customers particularly effectively and efficiently.

In general, it is also possible for the two entities Ei and E ₂ to communicate their whereabouts A and B to one another, and for data transmission to the central processing unit 5 to be dispensed with. For example, the algorithm 4 can also be executed on one or both entities Ei and E ₂ . Accordingly, one of the entities Ei and E ₂ transmits the starting point M determined by it back to the other entity Ei and E ₂ .

Claims

patent claims

1. Method for determining a starting point (M) between two entities (Ei, E ₂ ), wherein the entities (Ei, E ₂ ) are each set up to determine their location (A, B) and to communicate using a communication interface, characterized in that the whereabouts (A, B) of the entities (Ei, E ₂ ) are determined in map material (1), one consists of at least two, each with a route section (Pi,

P ₂ , P ₃ , P ₄ , P ₅ , R _d ) connected route points (2) composing route (3) between the two whereabouts (A, B) of the entities (Ei, E ₂ ) in the map material (1) is determined, and for iteratively determining a position of the starting point (M) on the route (3), the route sections (Pi, P2, P3, P4, P5, Pe) included in the route (3) are divided into sub-route sections (P31, P32, P33, P34, P ₃₅ ) are subdivided so that a stretch of route (3) that extends from the location (A, B) of a first entity (Ei, E ₂ ) to the starting point (M) can be covered in the same time and/or the same Has a path length, such as a route (3) stretching from the location (A, B) of a second entity (Ei, E ₂ ) to the starting point (M), with each entity (Ei, E ₂ ) using a means of transport assigned to it moved along route (3).

2. The method as claimed in claim 1, characterized in that the first (Ei) and second entity (E ₂ ) meet at the starting point (M) starting from their respective whereabouts (A, B).

3. The method according to claim 1, characterized in that at least one third entity (E3) travels from the starting point (M) along the route from the location (A) of the first entity (Ei) to the starting point (M) to the location (A) of the first entity (Ei) and at least one fourth Entity (E4) travels from the starting point (M) along the route that extends from the location (B) of the second entity (E2) to the starting point (M) to the location (B) of the second entity (E2).

4. The method according to any one of claims 1 to 3, characterized in that the whereabouts (A, B) of the entities (Ei, E2) are determined in map material (1) provided by at least two map providers, the different map material (1) specific whereabouts (A, B) of an entity (Ei, E2) are compared with each other.

5. The method as claimed in one of claims 1 to 4, characterized in that current traffic information is taken into account when calculating the route (3) between the first (Ei) and second entity (E2).

6. The method as claimed in one of claims 1 to 5, characterized in that at least one entity (Ei, E2, E3, E4) moves along the route (3) using one of the following means of transport: on foot; on a bike; with an e-scooter; by public transport, in particular by bus and/or train; with a car, in particular a car, truck and/or van; or with an autonomously controllable vehicle, in particular a drone, preferably a flying drone.

7. The method according to any one of the preceding claims, characterized in that average travel speeds for the respective entities (Ei, E2, E3, E4) are assumed to determine the starting point (M), the assumed average travel speeds for the respective entities (Ei, E2, E3, E4) depending on a means of transport you have chosen.

8. The method according to any one of claims 1 to 7, characterized in that an algorithm (4) for determining the position of the starting point (M) on the route (3) carries out at least the following steps:

calculating the route (3) between the locations (A, B) of the two entities (Ei, E2);

halving the calculated route (3) with respect to a travel length of the route (3) or a time required to travel the route (3) to determine a half distance;

As long as a current distance starting from one of the locations (A, B) is less than half the distance: adding the next subsequent route section (P2, P3, P4, Ps) to the current distance;

As soon as the current distance is greater than half the distance: subdividing the last added route section (P3) into n sub-route sections (P31, P32, P33, P34, P35); and

As long as the current distance minus the last added route section (P3) is less than half the distance: Adding the next subsequent sub-route section (P32, P33) to the current distance.

9. The method as claimed in one of claims 1 to 8, characterized in that the starting point (M) is recalculated taking into account a current whereabouts (A*, B*) of at least one of the entities.

10. The method according to any one of claims 1 to 9, characterized in that to determine the position of the starting point (M) on the route (3), at least one of the following criteria is additionally taken into account: fairness; a quantity of pollutants produced by moving at least one means of transport along the route (3), in particular a CC>2 quantity; an amount of energy required by at least one means of transport to move along the route (3); and/or costs incurred for moving at least one means of transport along the route (3).

11. System for determining a starting point (M) between two entities (Ei, E2), comprising at least two entities (Ei, E2, E3, E4), wherein the entities (Ei, E2) are each set up to determine their whereabouts and to share this via a communication interface, characterized in that at least the two entities (Ei, E2) are set up to carry out a method according to one of Claims 1 to 10.