NETWORK, PROGRAM AND COMPUTER PROGRAM PRODUCT FOR

IMPROVING DEVICE TO DEVICE COMMUNICATION

BACKGROUND

[0001] The present invention relates a method for improving device to device communication between a first user equipment and a second user equipment.

[0002] Furthermore, the present invention relates to a user equipment adapted for improved device to device communication between the user equipment and a second user equipment.

[0003] Additionally, the present invention relates to a system for improving device to device communication between a first user equipment and a second user equipment

[0004] Additionally, the present invention relates to a mobile communication network for improving device to device communication between a first user equipment and a second user equipment.

[0005] Furthermore, the present invention relates to a program and to a computer program product for improving device to device communication between a first user equipment and a second user equipment. [0006] The present invention addresses, inter alia, a method allowing at least two mobile terminal devices (or user equipments) that are capable of establishing a direct communication link between these devices (or user equipments) - hereinafter called device-to-device communication or device to device communication or D2D

communication - to discover each other, i.e. initially exchange information directly between these devices.

[0007] It is expected that the LTE (Long Term Evolution) system will allow for an increased usage of device to device communication. The LTE system and LTE-A (LTE Advanced) system comprises the Evolved Universal Mobile Telecommunications System (UMTS) Terrestrial Radio Access Network (E-UTRAN), and the Evolved Packet Core (EPC). The E-UTRAN typically comprises a plurality of base station entities, typically referred to as eNBs (evolved NodeBs) for macro-cells and HeNBs (Home-eNBs) for femto-cells, as well as the cellular terminals (or user equipments).

[0008] Device to device communication is currently being defined as a work item in the context of 3GPP (Third Generation Partnership Project), Release 12. The basic principle of LTE device to device communication (LTE D2D) is the possibility to allow for a direct communication between at least two devices (or user equipments) supporting a device to device communication mode. Within the context of the device to device communication, standardized in 3GPP, two modes are part of the 3GPP definitions: an infrastructure-based device to device communication mode and a direct device to device communication mode.

[0009] A further feature of the device to device communication is the so-called "discovery" functionality which allows at least two device-to-device-communication- enabled devices (or user equipments) to identify each other if these devices (or user equipments) are in the vicinity of each other. A still further feature of the device to device communication is the so-called "communication" functionality which allows the at least two device-to-device-communication-enabled devices involved in the discovery to initiate a direct communication between each other.

[0010] The discovery feature is of interest to critical communication users as well as commercial cellular mobile operators in order to explore new business opportunities with targeted mobile advertising as well as supporting the growing trend of social networking where the environment of the current location of the user equipment (i.e. the proximity of the current location) plays a more and more important role. Additionally, device to device communications, and especially proximity services, are likewise interesting for automotive applications in order to establish new services, e.g., for car-to-car communication, traffic management and traffic alert.

[0011] The successful execution of the discovery procedure between two user equipments typically requires the search for commonly used frequencies in order to enable a direct information exchange between the two user equipments. This might lead to situations where a successful execution of the discovery procedure is only possible with a considerable consumption of energy. SUMMARY

[0012] An object of the present invention is to provide a technically simple, effective and especially cost effective solution for enabling device to device proximity detection and/or device to device communication between at least two user equipments such that the energy consumption for the discovery procedure is reduced with respect to the state of the art.

[0013] The object of the present invention is achieved by a method for improving device to device proximity detection and/or device to device communication between a first user equipment and a second user equipment, the first user equipment and the second user equipment being enabled to use a device to device mode (D2D mode), wherein using the device to device mode for device to device proximity detection and/or device to device communication purposes between the first and second user equipments requires performing a discovery procedure between the first and second user

equipments,

at least the first user equipment being related to a mobile communication network comprising a core network and an access network, the access network of the mobile communication network comprising a base station entity, wherein a first frequency or frequency band is used for the reception of first control data by the first user equipment, the first control data being sent by the base station entity, and wherein a second frequency or frequency band is used for the reception of second control data by the second user equipment,

wherein the method comprises the following steps:

~ in a first step, the base station entity transmits, as part of the first control data, a first discovery resource configuration information and a second discovery resource configuration information, the first discovery resource configuration information indicating first air interface resources being possibly used for discovery purposes involving the first user equipment, the second discovery resource configuration information indicating second air interface resources being possibly used for discovery purposes involving the second user equipment,

~ in a second step, subsequent to the first step, the first user equipment uses the second discovery resource configuration information for performing a discovery procedure towards the second user equipments by using the second air interface resources.

[0014] It is thereby advantageously possible according to the present invention that a method for improving device to device proximity detection and/or device to device communication is provided, wherein the consumption of energy for the discovery procedure is reduced with respect to the state of the art. Moreover, the discovery procedure is preferably performed relatively fast because the second air interface resources are indicated to the first user equipment by the mobile communication network, e.g. a Public Land Mobile Network (PLMN). Thereby, the inventive method provides a relatively fast and efficient discovery for device to device proximity detection and/or device to device communication, especially when distinct first and second air interface resources are used by the first and second user equipment. Due to the transmission of the second discovery resource configuration information from the base station entity to the first user equipment, it is advantageously possible to inform the first user equipment not only about the first air interface resources but also about the second air interface resources such that the effort of searching for air interface resources required for the discovery of the second user equipment is reduced. The transmission of the second discovery resource configuration information as part of the first control data allows for further improvement of the device to device proximity detection and/or device to device communication method because further communication overhead due to a separate transmission of the second discovery resource configuration information is avoided.

[0015] According to the present invention it is furthermore preferred that device to device proximity detection and/or device to device communication between the first user equipment and a third user equipment is improved, wherein the third user equipment is enabled to use a device to device mode (D2D mode), wherein using the device to device mode for device to device proximity detection and/or device to device communication purposes between the first and third user equipments requires performing a discovery procedure between the first and third user equipments, wherein a third frequency or frequency band is used for the reception of third control data by the third user equipment, wherein the method comprises the following steps:

- in a further first step, the base station entity transmits, as part of the first control data, third discovery resource configuration information, the third discovery resource configuration information indicating third air interface resources being possibly used for discovery purposes involving the third user equipment,

- in a further second step, subsequent to the further first step, the first user equipment uses the third discovery resource configuration information for performing a discovery procedure towards the third user equipments by using the third air interface resources.

[0016] It is thereby advantageously possible that device to device proximity detection and/or device to device communication between the first user equipment, on the one hand, and the second and third user equipment, on the other hand, is improved with regard to the consumption of energy and performed relatively fast with respect to the state of the art. Similarly, the method according to the present invention may be used to improve the device to device proximity detection and/or device to device communication between the first user equipment and a plurality of other user equipments in addition to the second and third user equipments. Preferably, the third discovery resource configuration information indicating third air interface resources being possibly used for discovery purposes involving the third user equipment is of the same kind than the second discovery resource configuration.

[0017] According to the present invention it is preferred that the method further includes a third and a fourth step, wherein, in the third step, the base station entity or a further base station entity transmits, as part of the second control data, the first and second discovery resource configuration information, wherein in a fourth step, subsequent to the third step, the second user equipment uses the first discovery resource configuration information for performing a discovery procedure towards the first user equipment by using the first air interface resources. Moreover, the third user equipment is preferably camping on a further mobile communication network or any other mobile communication network of a plurality of other mobile communication networks.

[0018] It is thereby advantageously possible to provide the first and second resource configuration information to the first and to the second user equipment such that the device to device proximity detection and/or device to device communication is further improved.

[0019] According to a preferred embodiment of the present invention, the first control data are transmitted, by the base station entity, on a broadcast control channel (BCCH), the broadcast control channel being received by the first user equipment. [0020] Thereby, it is advantageously possible to distribute the second discovery resource configuration information to a plurality of first user equipments of the mobile communication network in a relatively simple and efficient manner.

[0021] According to a further preferred embodiment of the present invention, the second air interface resources are indicated, within the second discovery resource configuration information, by means of at least the following parameters:

~ a frequency indication,

~ a relative time offset to the system frame number (SFN), and

~ a radio resource block allocation. [0022] Thereby, it is advantageously possible to provide the first user equipment with a comparatively accurate indication of the second air interface resources such that the effort required for the discovery procedure performed by the first user equipment is reduced, in particular with respect to energy consumption. [0023] According to a further preferred embodiment of the present invention, the second discovery resource configuration information is transmitted using

- a system information block, the system information block comprising the first discovery resource configuration information for the device to device mode, or

- a separate system information block only comprising the second discovery resource configuration information.

[0024] It is thereby advantageously possible to further reduce communication overhead associated with the transmission of the second discovery resource

configuration.

[0025] According to a further preferred embodiment of the present invention, the first user equipment and the second user equipment are related to the mobile communication network, but the first frequency or frequency band and the second frequency or frequency band being different frequencies or frequency bands.

[0026] Thereby it is advantageously possible according to the present invention that the first and second user equipment are enabled to discover each other by means of the discovery procedure even in case that the user equipments are operating on different frequencies or frequency bands (inter-frequency discovery). According to the present invention, the first and second user equipments are preferably associated with the same mobile communication network, wherein an efficient inter-frequency discovery is realized across all frequencies used by the mobile communication network (intra-PLMN discovery). Alternatively, the first and second user equipments are preferably associated with different mobile communication networks, wherein an efficient inter-frequency discovery is realized between the different mobile communication networks (inter-PLMN discovery).

[0027] According to a further preferred embodiment of the present invention, the second user equipment is related to a further mobile communication network, the further mobile communication network using the second frequency or frequency band, wherein the first frequency or frequency band and the second frequency or frequency band are different frequencies or frequency bands. [0028] Thereby, it is advantageously possible to provide the first user equipment with the second discovery resource configuration information such that inter-PLMN discovery is enabled even in cases where a sharing of network resources between the different PLMNs (network sharing) is disabled. Preferably, a direct information exchange is realized between the first and second user equipment belonging to two different operators (PLMNs) while operating on different frequencies or frequency bands. Such an inter-PLMN discovery support especially enhances commercial success of the D2D discovery functionality, in particular for new localized services such as location dependent advertising or location aware social media. [0029] According to a further preferred embodiment of the present invention, the second air interface resources are either part of the second frequency or frequency band or of another frequency or frequency band and/or wherein the first air interface resources are either part of the first frequency or frequency band or of another frequency or frequency band. [0030] Thereby, it is advantageously possible that the first user equipment may use the second resource discovery configuration information to activate or deactivate a receiver of the first user element depending on the second resource discovery

configuration information. For example, the first user equipment may deactivate the receiver during a time interval in which receptions of discovery messages are not expected.

[0031] Furthermore, the present invention relates to a user equipment adapted for improved device to device proximity detection and/or device to device communication between the user equipment and a second user equipment, the user equipment and the second user equipment being enabled to use a device to device mode (D2D mode), wherein using the device to device mode for device to device proximity detection and/or device to device communication purposes between the user equipment and second user equipment requires performing a discovery procedure between the user equipment and the second user equipment,

at least the user equipment being related to a mobile communication network comprising a core network and an access network, the access network of the mobile communication network comprising a base station entity, wherein a first frequency or frequency band is used for the reception of first control data by the user equipment, the first control data being sent by the base station entity, and wherein a second frequency or frequency band is used for the reception of second control data by the second user equipment, wherein the user equipment is configured such that: - the user equipment receives, as part of the first control data sent by the base station entity, a first discovery resource configuration information and a second discovery resource configuration information, the first discovery resource configuration information indicating first air interface resources being possibly used for discovery purposes involving the user equipment, the second discovery resource configuration information indicating second air interface resources being possibly used for discovery purposes involving the second user equipment,

- the user equipment uses the second discovery resource configuration information for performing a discovery procedure towards the second user equipments by using the second air interface resources.

[0032] Thereby, it is advantageously possible to provide a user equipment capable of using the second discovery resource configuration information such that device to device proximity detection and/or device to device communication is improved with respect to the consumption of energy for the discovery procedure. [0033] Furthermore, the present invention relates to a system for improving device to device proximity detection and/or device to device communication between a first user equipment and a second user equipment, the system comprising a mobile

communication network, the first user equipment and the second user equipment, the first user equipment and the second user equipment being enabled to use a device to device mode (D2D mode), wherein using the device to device mode for device to device proximity detection and/or device to device communication purposes between the first and second user equipments requires performing a discovery procedure between the first and second user equipments,

at least the first user equipment being related to the mobile communication network comprising a core network and an access network, the access network of the mobile communication network comprising a base station entity, wherein a first frequency or frequency band is used for the reception of first control data by the first user equipment, the first control data being sent by the base station entity, and wherein a second frequency or frequency band is used for the reception of second control data by the second user equipment,

wherein the system is configured such that:

- the base station entity transmits, as part of the first control data, a first discovery resource configuration information and a second discovery resource configuration information, the first discovery resource configuration information indicating first air interface resources being possibly used for discovery purposes involving the first user equipment, the second discovery resource configuration information indicating second air interface resources being possibly used for discovery purposes involving the second user equipment,

- the first user equipment uses the second discovery resource configuration

information for performing a discovery procedure towards the second user equipments by using the second air interface resources.

[0034] Thereby, it is advantageously possible to provide a system being configured to apply the method according to the present invention, wherein the second discovery resource configuration information is provided to the first user equipment such that device to device proximity detection and/or device to device communication is improved with respect to the state of the art. According to a further embodiment of the present invention, the system is preferably at least one of an Earthquake and Tsunami Warning System (ETWS), a Public Warning System, an enhanced Multimedia Broadcast and Multicast System (eMBMS) and a Short Message Service (SMS) Cell Broadcast System.

[0035] Furthermore, the present invention relates to a mobile communication network for improving device to device proximity detection and/or device to device communication between a first user equipment and a second user equipment, the first user equipment and the second user equipment being enabled to use a device to device mode (D2D mode), wherein using the device to device mode for device to device proximity detection and/or device to device communication purposes between the first and second user equipments requires performing a discovery procedure between the first and second user equipments,

at least the first user equipment being related to the mobile communication network comprising a core network and an access network, the access network of the mobile communication network comprising a base station entity, wherein a first frequency or frequency band is used for the reception of first control data by the first user equipment, the first control data being sent by the base station entity, and wherein a second frequency or frequency band is used for the reception of second control data by the second user equipment,

wherein the mobile communication network is configured such that:

- the base station entity transmits, as part of the first control data, a first discovery resource configuration information and a second discovery resource configuration information, the first discovery resource configuration information indicating first air interface resources being possibly used for discovery purposes involving the first user equipment, the second discovery resource configuration information indicating second air interface resources being possibly used for discovery purposes involving the second user equipment, - the first user equipment uses the second discovery resource configuration

information for performing a discovery procedure towards the second user equipments by using the second air interface resources.

[0036] Thereby, it is advantageously possible to provide a mobile communication network, in particular a PLMN, wherein the second discovery resource configuration information is provided to the first user equipment such that the first user equipment may use the second discovery resource configuration in order to improve device to device proximity detection and/or device to device communication, in particular with respect to the consumption of energy. [0037] Additionally, the present invention relates to a program comprising a computer readable program code which, when executed on a computer or on a user equipment or a base station entity, or in part on the user equipment and in part on the base station entity, causes the computer or the user equipment or the base station entity to perform the inventive method. [0038] Still additionally, the present invention relates to a computer program product for using a user equipment with a base transceiver station, the computer program product comprising a computer program stored on a storage medium, the computer program comprising program code which, when executed on a computer or on a user equipment or a base station entity, or in part on the user equipment and in part on the base station entity, causes the computer or the user equipment or the base station entity to perform the inventive method.

[0039] These and other characteristics, features and advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention. The description is given for the sake of example only, without limiting the scope of the invention. The reference figures quoted below refer to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

[0040] Figures 1 and 2 schematically illustrate mobile communication networks being enabled for allowing the possibility to conduct device to device proximity detection and/or device to device communication between user equipments according to the present invention. [0041] Figure 3 schematically illustrate frequency bands being used by user equipments according to the present invention.

DETAILED DESCRIPTION [0042] The present invention will be described with respect to particular

embodiments and with reference to certain drawings but the invention is not limited thereto but only by the claims. The drawings described are only schematic and are non- limiting. In the drawings, the size of some of the elements may be exaggerated and not drawn on scale for illustrative purposes. [0043] Where an indefinite or definite article is used when referring to a singular noun, e.g. "a", "an", "the", this includes a plural of that noun unless something else is specifically stated.

[0044] Furthermore, the terms first, second, third and the like in the description and in the claims are used for distinguishing between similar elements and not necessarily for describing a sequential or chronological order. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the invention described herein are capable of operation in other sequences than described or illustrated herein.

[0045] In Figure 1 , a mobile communication network 100, especially a public land mobile network 100, is schematically shown, the mobile communication network 100 comprising an access network 1 10 and a core network 120. The mobile communication network 100 is preferably a cellular telecommunications network comprising typically a plurality of network cells, wherein two neighbouring cells are represented in Figure 1 by means of reference signs 10 and 1 1 . In the mobile communication network 100, a first user equipment 20 is camping on the mobile communication network 100 within the network cell 10, i.e. the first user equipment 20 is connected to or camping on a base station entity 1 1 1 serving the cell 10. Furthermore, a neighbour base station entity 1 12 serving the neighbour cell 1 1 is schematically shown. The first user equipment 20 uses a first frequency or frequency band 320 for the reception of first control data from the base station entity 1 1 1 . A second frequency or frequency band 321 is used for the reception of second control data by the second user equipment 21 . According to a preferred embodiment, the first user equipment 20 and the second user equipment 21 are both camping on the same mobile communication network 100. For example, the first and second user equipment 20, 21 are camping on the same network cell 10 (illustrated in Figure 1 ), i.e. the first and second user equipment 20, 21 are connected to or camping on the same base station entity 1 1 1 or the first and second user equipments 20, 21 are camping on neighbouring network cells 10, 1 1 of the mobile communication network 100, wherein, in this case, the second user equipment 21 receives the second control data from the mobile communication network 100 but using another frequency or frequency band than the frequency or frequency band used between the first user equipment 20 and the mobile communication network 100. According to an alternative embodiment of the present invention, the first user equipment 20 is camping on the mobile

communication network 100 and the second user equipment 21 is camping on a further mobile communication network 200 (illustrated in Figure 2), wherein, in this case, the second user equipment 21 receives the second control data from the further mobile communication network 200 (typically using another frequency or frequency band than the frequency or frequency band used by the mobile communication network 100 and the first user equipment 20).

[0046] According to the present invention, the first user equipment 20 and the second user equipment 21 are enabled to use a device to device mode (D2D mode) for device to device proximity detection and/or device to device communication. The device to device communication between the first and second user equipments 20, 21 is preferably either unidirectional or bidirectional. Preferably, a discovery procedure between the first and second user equipments 20, 21 is performed, when the device to device mode is used for device to device proximity detection and/or device to device communication purposes between the first and second user equipments 20, 21 .

[0047] After reception, by the first user equipment 20 from the base station entity 1 1 1 , of first and second discovery resource configuration information as part of the first control data, the first user equipment 20 uses the second discovery resource

configuration information for performing the discovery procedure towards the second user equipments 21 . Thereby, the first discovery resource configuration information are configured to indicate first air interface resources 340 (illustrated in Figure 3) being possibly used for discovery purposes involving the first user equipment 20 and the second discovery resource configuration information are configured to indicate second air interface resources 341 being possibly used for discovery purposes involving the second user equipment 20. The first user equipment 20 uses the second discovery resource configuration information for performing the discovery procedure towards the second user equipments 21 by using the second air interface resources 341 . [0048] The first user equipment 20 is configured to discover the second user equipment 21 by performing the discovery procedure, when the first and second user equipments 21 , 22 are operating on different frequencies or frequency bands (inter- frequency discovery). For example, the first and second user equipments 21 , 22 are associated with the same mobile communication network 100 such that an inter- frequency discovery is realized across all frequencies used by the (same) mobile communication network 100 (intra-PLMN discovery). Alternatively, the first and second user equipments 20, 21 are associated with different mobile communication networks 100, 200 (see Figure 2) such that an inter-frequency discovery is realized between the different mobile communication networks 100, 200 (inter-PLMN discovery). In both alternatives, the mobile communication network 100 is associated with a first frequency or frequency band 320 being used by the first user equipment 20 for the reception of first control data.

[0049] In the intra-PLMN discovery case, the mobile communication network 100 is associated with a second frequency or frequency band 321 (cf. Figure 3) being used by the second user equipment 21 for the reception of second control data. This means, that both user equipments 20, 21 (i.e. the first and second user equipment 20, 21 ) are operating on their own dedicated frequencies or frequency bands. For example, the first user equipment 20 is registered to the mobile communication network 100 on the first frequency or frequency band 320 and the second user equipment 21 is registered to the mobile communication network 100 on the second frequency or frequency band 321 . Preferably, the first user equipment 20 is configured to listen to a broadcast control channel (BCCH) of the serving network cell 10 of the mobile communication network 100 on which the first user equipment 20 is camping on. Preferably, the configurations of the air interface resources (first and/or second discovery resource configuration information) to be used for device to device discovery are transmitted on a defined System

Information Block (SIB) or an enhanced SIB of the Broadcast Control Channel (BCCH) of the mobile communication network 100.

[0050] In Figure 2, a further mobile communication network 200, especially a further public land mobile network 200, is schematically shown in addition to the mobile communication network 100. The further mobile communication network 200 comprises a further access network 210 and a further core network 220. The further mobile communication network 200 is preferably a cellular telecommunications network comprising typically a plurality of network cells, wherein two further neighbouring cells are represented in Figure 2 by means of reference signs 12 and 13. Here, the inter-PLMN discovery case is shown. In the further mobile communication network 200, the second user equipment 21 is camping on the further mobile communication network 200 within the further network cell 12, i.e. the second user equipment 21 is connected or camping on a further base station entity 21 1 serving the further cell 12. In addition, a further neighbour base station entity 212 serving the further neighbour cell 13 is illustrated. [0051] According to the inter-PLMN discovery case, the mobile communication network 100 and the further mobile communication network are both operating on their own dedicated frequencies. This means, that the mobile communication network 100 operates on the first frequency or frequency band 320 and the further mobile

communication network 200 operates on the second frequency or frequency band 321 . Preferably, the mobile communication network 100 and the further mobile communication network 200 at least partially overlap, wherein the mobile communication network 100 and the further mobile communication network are, for example, located in the same country or in country border areas. The first user equipment 20 is registered to the mobile communication network 100 on the first frequency or frequency band 320 and the second user equipment is registered to the further mobile communication network 200 on the second frequency or frequency band 321 , wherein preferably the first and second user equipments 20, 21 are each configured to listen to the broadcast control channel of the associated serving network cell 10 or 12, respectively. Preferably, the configurations of the air interface resources (discovery resource configuration information) to be used for device to device discovery are transmitted on a defined System Information Block (SIB) or an enhanced SIB of the Broadcast Control Channel (BCCH) of the mobile

communication network 100 and/or a further Broadcast Control Channel of the further mobile communication network 200. Preferably, device to device proximity detection and/or device to device communication is realized even when network sharing or national roaming is disabled. Thereby, it is advantageously possible to enable inter-PLMN discovery support within a country and/or between multiple countries in case of country border areas.

[0052] Preferably, the support of inter-PLMN discovery is enabled, which means that the first user equipment 20 receives the information of inter-PLMN discovery resource allocation (second discovery resource configuration information being related to the further mobile communication network 200) from the mobile communication network 100.

Preferably, a first and a second discovery resource configuration information is transmitted as part of the first control data, wherein the first control data indicates - e.g. by using an additional single bit - that an inter-PLMN frequency or frequency band (second frequency or frequency band 321 ) is used for the reception of discovery messages from the second user equipment 21 . According to the present invention, the second discovery resource configuration information preferably comprises an

identification element for identification of the further mobile communication network 200.

[0053] In Figure 3 frequency bands 320, 321 being used by user equipments 20, 21 are schematically illustrated, wherein the frequency bands 320, 321 are shown as distinct frequency bands, e.g. licensed frequency bands, of a frequency spectrum 300.

Furthermore, first air interface resources 340 and second air interface resources 341 are schematically illustrated. Preferably, the first air interface resource 340 is a contiguous part of the first frequency band 320, wherein preferably the second air interface resource 341 is a contiguous part of the second frequency band 321 . [0054] The second air interface resources 341 are preferably indicated by means of at least three parameters, i.e. a frequency, a relative time offset (resource allocation X) to the system frame number (SFN) and a radio resource block allocation. According to the present invention, a system information block (SIB) is preferably used for the

transmission of the second discovery resource configuration information, wherein the SIB consists at least of the resource allocation X and a parameter YZ which describes the resource allocation at a point in time to which the relative time offset to the SFN points. It is thereby advantageously possible that the first user equipment 20 (which uses the first frequency or frequency band 320) is provided with information about the resource allocation associated with the first frequency or frequency band 320. Preferably, the first user equipment 20 uses the second discovery resource configuration information for a transmission and/or reception of discovery messages.