EP4282193A1

EP4282193A1 - Control method for automatically establishing or automatically switching vehicle communication for data exchange between a vehicle and a remote station

Info

Publication number: EP4282193A1
Application number: EP21834761.5A
Authority: EP
Inventors: Osman Aydin
Original assignee: Mercedes Benz Group AG
Current assignee: Mercedes Benz Group AG
Priority date: 2021-01-19
Filing date: 2021-12-08
Publication date: 2023-11-29
Also published as: KR20230104248A; WO2022156953A1; DE102021000246A1; CN116636304A; JP2024504111A

Abstract

The invention relates to a control method for automatically establishing or automatically switching vehicle communication for data exchange between a vehicle (1) and a remote station (2), wherein the vehicle (1) is driven with various levels of autonomy. The control method according to the invention is characterised in that the data is transmitted between the vehicle (1) and the remote station (2) via at least one of the following types of network connection: - a network connection (3) in a terrestrial network (4); - a network connection (3) in a non-terrestrial network (5); - parallel network connections (3) in a terrestrial and a non-terrestrial network (4, 5); wherein the type of network connection is selected on the basis of a currently set and/or requested level of autonomy.

Description

Control method for the automatic establishment or for the automatic switching of a vehicle communication for data exchange between a vehicle and a remote station

The present invention relates to a control method for automatically setting up or automatically switching over a vehicle communication for data exchange between a vehicle and a remote station according to the preamble of claim 1.

It is known from the field of data transmission in mobile radio networks to adapt the quality and speed of data transmission on the basis of user requirements. For example, secured by an individual contract design, a user can be assured of a specific transmission quality and/or transmission speed by a provider, which can be defined, for example, by specifying quality of service requirements (QoS: Quality of Service). Such a quality of service describes the quality of a communication service from the point of view of the respective user and contains various quality requirements for data transmission.

It is also generally known that a suitable network connection is selected as a function of the quality of service requirements.

Nowadays, terrestrial networks, in particular mobile radio networks, and non-terrestrial networks, in particular satellite-supported communication, are available for wireless data transmission on a larger scale. WO 98/10521 A2 discloses a mobile terminal that automatically switches between a satellite based network and a terrestrial network. The switching can take place depending on a data protocol selected by a user or automatically. In order to be able to ensure particularly high data transmission rates for certain users in the mobile network, so-called network slicing was also proposed, see "5G Service-Guaranteed Network Slicing White Paper" version 1.0, edition of February 28, 2017 (China Mobile Communications Corporation, Huawei Technologies Co ., Ltd., Deutsche Telekom AG, Volkswagen).

Network connections are therefore available for mobile data transmission in networks that guarantee the highest data transmission quality and transmission speeds. However, using such network connections and reserving corresponding connection capacities is associated with comparatively high costs. In addition, there is a risk of overloading such high-speed network connections with the progressive introduction of the technologies of the "Internet of Things", for example in m2m (machine-to-machine) services or in the development of autonomous driving of motor vehicles. Particularly in the case of autonomous or semi-autonomous motor vehicles, a large amount of data is transmitted between a vehicle and a remote station to control the vehicles, as the present invention relates, the remote station being one or more other vehicles, parts of a traffic infrastructure or manually operable terminals can act. If all this data is transmitted over the available networks with the highest data quality and data transmission rate, this is associated with high costs and a correspondingly high utilization of these networks.

US 2019/0258251 A1 discloses a system that improves the functionality of autonomously driving vehicles in autonomy levels 3 to 5, with extremely adaptive supercomputers being used in a platform communicating with the vehicles in order to improve the learning success of the individual vehicles. Data is transmitted between the vehicle and a remote station, namely a cloud-based infrastructure that includes supercomputers. Data from each Autonomy Level 3 to 5 vehicle shall be transmitted over a cellular network or other terrestrial network such as LTE where available, WCDMA, UMTS, CDMA2000, HSPA+, GSM, or a satellite network to the cloud-based infrastructure. The cloud-based infrastructure analyzes this data and then transmits an update to the self-driving vehicles.

US 9 565 625 B1 discloses a selection of best available network connections when a vehicle is moving along a route. A network coverage map is generated, which the vehicle can use to determine which network is available at which location and with which signal strength. The vehicle can thereby select one or more types of network connections in different areas along a route in order to optimize communication.

US 2017/0219364 A1 discloses semi-autonomous or fully autonomous vehicles, with a navigation system taking into account, in addition to the conventional parameters, the portion of a route on which the vehicle can drive autonomously. As a result, the driver can preferentially select the routes on which the vehicle drives largely autonomously.

WO 2020/107991 A1 discloses a method, a device and a system for autonomous vehicles.

The present invention is based on the object of specifying a control method for automatically setting up or automatically switching vehicle communication for data exchange between a vehicle and a remote station, with which the costs and network utilization of particularly technology-intensive and cost-intensive networks can be reduced.

The object according to the invention is achieved by a control method having the features of claim 1. The dependent claims describe advantageous and particularly expedient refinements of the invention.

According to the invention, all data is no longer transmitted using the best available network connection, but instead an available network connection is specifically selected depending on the level of autonomy with which the vehicle is currently being driven or with which the vehicle is to be driven. In this way, for example, unnecessary parallel network connections (multi-connectivity connections) in different networks can be avoided, which would otherwise increase the operating costs and the network utilization of these networks. Network resources are thus used more efficiently than before.

In detail, according to the control method according to the invention for automatically setting up a new vehicle communication or for automatically switching over an existing vehicle communication for data exchange between a vehicle and a remote station, the vehicle being driven in different autonomy levels, the data between the vehicle and the remote station via at least one of the the following network connection types, namely a network connection in a terrestrial network, a network connection in a non-terrestrial network and parallel network connections in a terrestrial and non-terrestrial network, with the selection of the network connection type depending on a currently set and/or requested autonomy level.

The autonomy levels can be defined in accordance with SAE J3016, in the version applicable on the priority date of the present application. In particular, a definition of five autonomy levels is provided, with no automation provided for level 0, i.e. all aspects of the dynamic driving task are carried out consistently by the human driver, even if supporting warning or intervention systems are used, and full automation in level 5 is envisaged, with a consistent execution of all aspects of the dynamic driving task by an automated driving system under all driving and environmental conditions that could be managed by a human driver. In level 1, the driver is supported in certain driving situations by driver assistance systems that intervene with the information about the driving environment by accelerating, decelerating or steering and with the expectation that the human driver will take over all remaining dynamic driving tasks. In level 2, the driver is supported in certain driving situations by one or more driver assistance systems, which intervene with the information about the driving environment, both accelerating/decelerating and steering, and with the expectation that the human driver will take care of everything remaining dynamic driving tasks. In stage 3, dependent automation occurs with all aspects of the dynamic driving task, except that the human driver takes control of the vehicle when requested to intervene. Level 4 describes highly automated driving with all aspects of the dynamic driving task, even if the human driver does not intervene when requested and takes control of the vehicle.

In particular, the fastest and/or highest-quality network connection type can be selected when the autonomy level is set and/or requested at a comparatively high level, for example at level 3, 4 or 5 according to one embodiment, only at level 4 or 5 according to another embodiment, or according to another embodiment can only be selected at level 5. If available, the simultaneous use of at least one terrestrial and one non-terrestrial network is selected for this purpose by setting up the parallel network connections mentioned.

According to the invention, the best and most efficient network connection can be selected because the network connections in the terrestrial network and the network connections in the non-terrestrial network are independent of each other. This means that an adequate network connection can be made available in extremely large geographical areas.

If parallel network connections are used in a terrestrial and non-terrestrial network, the connection can be established in accordance with EN-DC (E-UTRA-NR Dual Connectivity), SUL (Supplement Uplink) or SDL (Supplement Downlink) or even as carrier aggregation (CA) as described in ETSI or 3GPP Telecommunications Standards in the version in force on the priority date of the present application.

Particularly preferably, the network connection type is additionally selected as a function of software applications and/or hardware applications activated and/or requested in the vehicle, each of which has one of a number of quality of service requirements (QoS). For example, the selection of the network connection type depending on the vehicle user interface activated app and/or an app activated on a smartphone connected to the vehicle user interface or based on settings in the app.

The quality of service requirements can differ, for example, by the latency, the jitter, the data error rate, the packet loss rate and/or by the data throughput. In particular, the quality of service requirements can differ by different Rx levels, Tx levels and/or by different RxQual values.

According to a particularly advantageous embodiment of the invention, the network connection type is selected as a function of the signal propagation time currently reached and/or a predetermined signal propagation time.

Network connections with different signal propagation times and/or different data throughput rates can be selected within the terrestrial network and/or within the non-terrestrial network, and one of these network connections within the corresponding network is selected depending on the set and/or requested autonomy level and/or in Dependence on the software applications and/or hardware applications activated and/or requested in the vehicle. This enables even better optimization of the network connection selection and extremely efficient use of the available networks to be achieved.

The data transmission in the non-terrestrial network takes place in particular via satellites.

The data transmission in the terrestrial network takes place, for example, via one or more mobile radio networks, in particular with different mobile radio standards.

Particularly preferably, individual satellites and/or satellite groups on different earth orbits can be selected for data transmission and these satellites and/or satellite groups are selected depending on the set and/or requested autonomy level and/or depending on the level of autonomy in the vehicle activated and/or requested software applications and/or hardware applications. For example, at a comparatively higher autonomy level, a satellite that is comparatively closer to Earth and/or a satellite group that is comparatively closer to Earth can then be selected, in particular a satellite or a satellite group on an orbit that is comparatively closer to Earth.

Correspondingly, with a comparatively higher level of autonomy and with a network connection in a terrestrial network, a mobile radio standard with a comparatively higher data transmission rate can be selected if different high data transmission rates are available to be selected in different mobile radio standards.

In the case of terrestrial networks, WLAN-based network connections can preferably also be selected in addition or as an alternative to mobile radio networks. In this case, too, the illustrated selection of connections with a higher data transmission rate can take place with a comparatively higher level of autonomy.

In the case of non-terrestrial networks, in addition to or as an alternative to satellite-based networks, drone-based networks with appropriate network connections and the selection of the appropriate network connection, as shown, can also be used.

Quality of service requirements that can be used within the scope of the present invention to select the type of network connection are disclosed, for example, in 3GPP TS 22.885 and TS 22.186, each in the version valid on the priority date of the present application.

The invention will be described below using an exemplary embodiment and the figures as an example.

show: 1 shows the schematic representation of an automatic setup according to the invention or an automatic switching of a vehicle communication from a terrestrial network to a non-terrestrial network;

Fig. 2 shows an automatic establishment or an automatic switching of a vehicle communication according to the present invention from a non-terrestrial network to a terrestrial network;

3 shows a corresponding switching from a terrestrial network to parallel network connections in a terrestrial and non-terrestrial network; and

4 shows a corresponding switching from a non-terrestrial network to parallel network connections in a terrestrial and a non-terrestrial network.

FIG. 1 shows a vehicle 1 which is connected to a remote station 2 via a network connection 3 and exchanges data with the remote station 2 via these network connections 3 . In this case, the vehicle 1 is controlled autonomously, for example, in a comparatively low autonomy level, for which purpose the data exchange takes place. The network connection 3 is established via a terrestrial network 4 . The terrestrial network 4 includes, for example, one or more selectable mobile radio networks 7 with corresponding transmission masts.

If the level of autonomy is now increased, a qualitatively higher and/or faster available network connection 3 should be used. In the exemplary embodiment shown in FIG. 1, this improved network connection 3 can be established via a non-terrestrial network 5, which establishes the network connection 3 via satellite 6. Accordingly, the network connection 3 is switched over to the non-terrestrial network 5 when the comparatively higher autonomy level is requested or set.

In the situation shown schematically in FIG. 2, it is determined, for example, that a network connection 3 in a terrestrial network 4 is better than the set network connection 3 in the non-terrestrial network 5, with always the comparatively high level of autonomy is still set. Network connection 3 is therefore switched to terrestrial network 4.

According to FIG. 3, either an even higher autonomy level should now be set or the existing network connection 3 via the terrestrial network 4 is not fully sufficient for data exchange and the sole use of a network connection 3 in a non-terrestrial network 5 is also insufficient. Therefore, there is a switchover to parallel network connections 3 in a terrestrial and a non-terrestrial network 4, 5.

The situation according to FIG. 4 corresponds to that of FIG. 3, except that initially there was only one network connection 3 in a non-terrestrial network 5 .

Claims

Control method for the automatic establishment or for the automatic switching of a vehicle communication for data exchange between a vehicle (1) and a remote station (2), the vehicle (1) being driven in different autonomy levels, characterized in that the data between the vehicle (1) and the remote station (2) via at least one of the following network connection types:

- a network connection (3) in a terrestrial network (4);

- a network connection (3) in a non-terrestrial network (5);

- parallel network connections (3) in a terrestrial and a non-terrestrial network (4, 5); wherein the network connection type is selected depending on a currently set and/or requested autonomy level. Control method according to claim 1, characterized in that the selection of the network connection type also depends on the vehicle (1) activated and / or requested software applications and / or hardware applications, each having one of several quality of service requirements. Control method according to Claim 2, characterized in that the quality of service requirements differ in terms of the latency, the jitter, the data error rate, the packet loss rate and/or the data throughput. Control method according to one of Claims 1 to 3, characterized in that the selection of the network connection type also takes place as a function of the currently reached and/or a predetermined signal propagation time. Control method according to one of Claims 1 to 4, characterized in that within the terrestrial network (4) and/or within the non-terrestrial network (5) network connections (3) with different signal transit times and/or data throughput rates can be selected and the selection of one of these network connections ( 3) depending on the set and/or requested autonomy level and/or the software application and/or hardware application activated and/or requested in the vehicle (1). Control method according to one of Claims 1 to 5, characterized in that the data is transmitted in the non-terrestrial network (5) via satellites (6). Control method according to Claims 5 and 6, characterized in that individual satellites (6) and/or satellite groups on different earth orbits can be selected for data transmission and the selection of the satellites (6) and/or satellite groups depends on the set and/or requested autonomy level and /or the software application and/or hardware application activated and/or requested in the vehicle (1). Control method according to Claim 7, characterized in that at a comparatively higher level of autonomy, a satellite (6) which is comparatively closer to the earth and/or a satellite group which is comparatively closer to the earth is selected. Control method according to one of Claims 1 to 8, characterized in that the data transmission in the terrestrial network (4) takes place via one or more mobile radio networks (7) with different mobile radio standards. Control method according to Claims 5 and 9, characterized in that at a comparatively higher level of autonomy, a mobile radio standard with a comparatively higher data transmission rate is selected.