Patent Publication Number: US-2023156642-A1

Title: Enabling Multiple Numerologies in a Network

Description:
RELATED APPLICATIONS 
     This application is a continuation of U.S. patent application Ser. No. 15/500,326 filed 30 Jan. 2017, which is a U.S. National Phase Application of PCT/SE2016/051083 filed 3 Nov. 2016. The entire contents of each aforementioned application is incorporated herein by reference. 
    
    
     TECHNICAL FIELD 
     The invention relates to a method for enabling multiple numerologies in a network, as well as a user equipment, a base station, a computer program and a computer program device of the network. 
     BACKGROUND 
     The fifth generation of mobile telecommunications and wireless technology is not yet fully defined but in an advanced draft stage within 3rd Generation Partnership Project (3GPP). It includes work on 5G New Radio (NR) Access Technology. Long term evolution (LTE) terminology is used in this disclosure in a forward looking sense, to include equivalent 5G entities or functionalities although a different term is specified in 5G. A general description of the agreements on 5G NR Access Technology so far is contained in 3GPP technical report (TR) 38.802 v0.3.0 (2016-10), of which a draft version has been published as R1-1610848. 
     In 3GPP, there is an ongoing study item that looks into a NR interface for 5G. Terms for denoting this new and next generation technology have not yet converged, so the terms NR and 5G will be used interchangeably. 
     One of the first major decisions that the 3GPP work-group RAN1 needs to take for NR concerns is what is often denoted with the terms “numerology” and “frame structure”. In 3GPP RAN1, the term numerology is used to determine important numeric parameters that describe some rather fundamental aspects of the OFDM radio interface, such as subcarrier spacing. OFDM symbol length, cyclic prefix length, number of symbols per subframe or slot, subframe length, and frame length. Some of these terms could also fall under the term frame structure, such as e.g. frame length, number of subframe per frame, subframe length, and location and number of symbols in a slot, frame or subframe that carry control information, and location of channels that carry data. In NR a subframe is 1 ms and establishes a 1 ms clock. Transmissions use slots or mini-slots. A slot consists of 7 or 14 symbols, 7 symbols for subcarrier spacings less than or equal to 60 kHz and 14 symbols for subcarrier spacings greater than 60 kHz. 
     In addition, the term frame structure can comprise a variety of additional aspects that reflect the structure of frames, subframes and slots, for example the positioning and density of reference signals (pilot signals), placement and structure of control channels, location and length of guard time for uplink to downlink switching (and vice versa) for time division-duplexing (TDD), and time-alignment. Generally, numerology and frame structure encompass a set of fundamental aspects and parameters of the radio interface. 
     LTE supports a single sub-carrier spacing of 15 kHz. For some other parameters in LTE, there is some additional flexibility. For example, it is possible to configure the length of the cyclic prefix and the size of the control region within a subframe. Similarly, LTE can support multiple different frame structures. e.g. for frequency division-duplexing (FDD), TDD, and Narrowband Internet of Things (NB-IoT), respectively. 
     3GPP TSG RAN WG1 has recently agreed that that it shall be possible support mixed sub-carrier spacing on the same carrier in NR. The feasibility of mixed subcarrier spacing was studied e.g. in 3GPP contribution R1-163224, where it was shown that the interference between non-orthogonal sub-carriers can be mitigated successfully. 
     SUMMARY 
     An object of embodiments presented herein is how to enable mixed numerologies in the 50 NR technology. 
     According to a first aspect there is presented a method for enabling multiple numerologies in a network. The method is performed by a user equipment (UE) and comprises receiving system information in a first search space on a broadcast channel with a first numerology, determining a second search space from the received system information, and receiving further information in the second search space with a second numerology. 
     The first numerology may be different from the second numerology. From the point of view of the UE executing the method of the first aspect, the case where the first and second numerologies are different is supported but is not a prerequisite for operation of the UE. The UE may as well support and function in a situation the first and second numerologies are equal or equivalent, according to a configuration applicable at a given point in time. Put differently, the second numerology is configurable without being restricted by the first numerology, or without dependence on properties of the first numerology. 
     The broadcast channel may be a physical broadcast channel (PBCH). 
     The step of receiving system information may further comprise detecting system information 
     The method may further comprise receiving synchronization information prior to receiving the broadcast channel. Based on the reception of the synchronization information received on one or multiple synchronization channels, the UE may deduce the numerology of the search space or region of the broadcast channel. 
     The second numerology may be indicated in the received system information. 
     The second search space may be UE specific. 
     The second search space may be a common search space. 
     The step of determining may further comprise determining a third search space having a third numerology. 
     According to a second aspect there is presented a method for enabling multiple numerologies in a network. The method is performed by a base station (BS) and comprises sending system information in a first search space on a broadcast channel with a first numerology and sending further information in a second search space with a second numerology. 
     The first numerology may be different from the second numerology. 
     The broadcast channel may be a physical broadcast channel (PBCH). 
     The method may further comprise sending synchronization information for a broadcast channel. 
     According to a third aspect there is presented a UE for enabling multiple numerologies in a network. The UE comprises a processor and a computer program product. The computer program product stores instruction that, when executed by the processor, causes the UE to receive system information in a first search space on a broadcast channel with a first numerology, determine a second search space from the received system information, and to receive further information in the second search space with a second numerology. 
     According to a fourth aspect there is presented a BS for enabling multiple numerologies in a network. The BS comprises a processor and a computer program product. The computer program product stores instruction that, when executed by the processor, causes the BS to send system information in a first search space on a broadcast channel with a first numerology, and to send further information in a second search space with a second numerology. 
     According to a fifth aspect there is presented a UE for enabling multiple numerologies in a network. The UE comprises a communication manger and a determination manager. The communication manager is for receiving system information in a first search space on a broadcast channel with a first numerology, and for receiving further information in the second search space with a second numerology. The determination manager is for determining a second search space from the received system information. 
     According to a sixth aspect there is presented a BS for enabling multiple numerologies in a network. The BS comprises a communication manager for sending system information in a first search space on a broadcast channel with a first numerology, and for sending further information in a second search space with a second numerology. 
     According to a seventh aspect there is presented a computer program for enabling multiple numerologies in a network. The computer program comprises computer program code which, when run on a user equipment (UE), causes the UE to receive system information in a first search space on a broadcast channel with a first numerology, determine a second search space from the received system information, and to receive further information in the second search space with a second numerology. 
     According to an eighth aspect there is presented a computer program for enabling multiple numerologies in a network. The computer program comprises computer program code which, when run on a BS, causes the BS to send system information in a first search space on a broadcast channel with a first numerology, and to send further information in a second search space with a second numerology. 
     According to a ninth aspect there is presented a computer program product comprising a computer program and a computer readable storage means on which the computer program is stored. 
     Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to “a/an/the element, apparatus, component, means, step, etc.” are to be interpreted openly as referring to at least one instance of the element, apparatus, component, means, step, etc., unless explicitly stated otherwise. The steps of any method disclosed herein do not have to be performed in the exact order disclosed, unless explicitly stated. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention is now described, by way of example, with reference to the accompanying drawings, on which: 
         FIG.  1    is a schematic diagram illustrating an environment where embodiments presented herein can be applied: 
         FIG.  2    is a schematic diagram illustrating frequency multiplexing of sub-band regions with different sub-carrier spacings; 
         FIG.  3    is a schematic diagram illustrating search spaces according to an embodiment presented herein; 
         FIG.  4    is a schematic diagram illustrating search spaces according to an embodiment presented herein; 
         FIG.  5    is a schematic diagram illustrating search spaces according to an embodiment presented herein; 
         FIGS.  6 A- 6 B  arc flowcharts illustrating methods for embodiments presented herein; 
         FIGS.  7 - 8    are schematic diagrams illustrating some components of devices presented herein; and 
         FIGS.  9 - 10    are schematic diagrams showing functional modules of devices presented herein. 
     
    
    
     DETAILED DESCRIPTION 
     It is noted that the invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout the description. 
     Herein the terms user equipment (UE), terminal, handset etc. interchangeably to denote a device that communicates with a network infrastructure. The term should not be construed as to mean any specific type of device, i.e. it applies to them all, and the embodiments described herein are applicable to all devices that use the concerned solution to solve the problems as described. Similarly, a base station (BS) is intended to denote the node in the network infrastructure that communicates with the UE. Different names may be applicable, such as NB, eNB, gNB, and the functionality of the BS may also be distributed in various ways. For example, there could be a radio head terminating parts of the radio protocols and a centralized unit that terminates other parts of the radio protocols. The term BS will refer to all alternative architectures that can implement the concerned invention, and no distinction between such implementations will be made. 
       FIG.  2    provides a schematic illustration of frequency multiplexing of three sub-band regions with different numerology. In the illustration, there are three different numerologies provided, such as three different carrier frequency portions that use different subcarrier spacing. 
     It should be noted that many other parameters are likely to be dependent, at least in part, on the subcarrier spacing. For example, the symbol length in OFDM is a function of the sub-carrier spacing. The slot length, which is defined in number of symbols or milliseconds, depends for example on selected numerology. Common to many of these parameters is that a receiver needs to know, or will at least greatly benefit from knowing beforehand, what parameters are used by the transmitter when transmitting a signal to the receiver. For example, a UE benefits from knowing the sub-carrier spacing used by a transmitting BS, so that the UE can reduce the hypotheses of different sub-carrier spacings used by the BS when trying to decode a signal. This applies to many parameters, including but not limited to the ones described above. Some parameters can be either identified by blind decoding, but if there are too many unknown parameters, the identification task will place a heavy processing burden on the UE. 
     The term “numerology” will herein denote these parameters or at least some of the parameters. More precisely, in a system where one of the enumerated parameters is not configurable, numerology may be understood as not including non-configurable parameters. Occasionally, the expression “a numerology” may denote a set of values to be assigned to the configurable parameters. 
     Current agreements in RAN1 includes a subcarrier spacing that scales according to 2 m ×15 kHz, with m an integer or preferably m≥0. It is also agreed that a physical resource block consists of 12 subcarriers. A subframe duration is also fixed to 1 ms. A slot consists of 7 or 14 symbols, 7 symbols for subcarrier spacings less than or equal to 60 kHz and 14 symbols for subcarrier spacings greater than 60 kHz. 
     As already noted, 3GPP TSG RAN WG1 has agreed that 5G NR should support multiple numerologies within a carrier. Having different numerologies within a carrier can be attractive e.g. to simultaneously meet requirements for low latency for one subset of UEs, and at the same time support good coverage for another set of UEs. In more generally terms, different sub-bands on a carrier using different numerologies can then be used for transmissions to and from the different UEs, where the different UEs have different demands on service quality. 
     However, problems also arise with this flexibility in supporting multiple numerologies on a carrier. In particular a receiver, such as a UE, would greatly benefit from knowing beforehand what numerology that is to be assumed when trying to decode a signal from a transmitter. One challenge is that, when the UE first finds and connects to a cell, it does not necessarily know what numerology is applied on the carrier in the cell, and in particular, it does not know if there are sub-band portions that apply different numerologies. 
     For the UE, it may be difficult or demanding to implement a solution where the UE knows little or nothing about the downlink signal structure. i.e. the numerology, and has to try out a large number of different assumptions through blind decoding before it can decode the signal from the BS. This problem is particularly severe when a UE is to establish a connection with a BS, i.e. when the UE has not yet received much specific information from the BS about how the BS intends to transmit signals to the UE. 
     A common and known solution to the problem of informing UEs about cell or carrier parameters is to broadcast such information in system information from the BS to UEs within a coverage area of the BS. By that method, basic parameters such as cell bandwidth, frame structure, cyclic prefix etc. can be made available periodically to all UEs within the proximity of the BS. However, this approach has some significant drawbacks, including:
         1. Successful reception of the concerned system information requires that the UE already knows some basic information about the numerology where the system information is transmitted. In LTE, for example, the UE is aware of the specified constant sub-carrier spacing of 15 kHz and does not have to hypothesize in this regard. In LTE, based on synchronization information, the UE will also know the timing and the location of certain basic system information, such as master information block (MIB) and then subsequently system information block type1 (SIB1), so that it can subsequently gain more information about e.g. the frame structure in the cell.   2. The carrier on which system information is broadcast will be subject to considerable load. Broadcast system information has to be repeated relatively frequently, and if there is intent to provide a significant flexibility by having many configurable numerology parameters, the approach would likely to result in significant overhead.   3. At high frequencies, the realization of signaling by broadcasting methods over a large area can be very difficult, if not impossible, as the propagation conditions may require either beamforming or very prudent coding and modulation to ensure that the broadcast information can be received by UEs regardless of their location.       

     Thus, there is a need to provide a solution that can support or enable multiple numerology scenarios, distribution of fundamental parameters without placing excessive load on a broadcast channel, so that a UE can quickly and unambiguously learn what numerologies are supported in different sub-band portions of a carrier. There is also a need for a solution for forward compatibility, so that new numerologies expressed by physical layer parameters and e.g. new channel and frame structure designs can be put to use in sub-band portions of a carrier. By such an approach, the backwards-compatible sub-portion of the carrier can be reduced to a minimum, and new sub-band solutions can be put to use in an efficient way. 
     Technologies addressing the aforementioned problems as outlined above are presented. 
     Embodiments are presented intended to enable a UE to acquire information about sub-band numerologies on a carrier with minimal overhead including low processing requirements. 
     Embodiments are also presented for a BS that signals information to a UE about sub-bands with specific numerologies, wherein the solution provides great flexibility, low overhead and future compatibility required e.g. when new transmission solutions are introduced in later revisions of the network. 
     Synchronization signals may be received over a channel or channels with a known numerology. Alternatively, a set of available numerologies is limited, or preferably significantly limited, so that the burden for decoding synchronization signals is manageable. The UE then may decode a physical broadcast channel (PBCH), which may have a numerology that is fixed, or otherwise based on the detection and information deduced from the synchronization. Information on the PBCH may carry information about common and/or additional search spaces, wherein the information may include information about the numerology applied on these search spaces. Data, such as system information, scheduled on the common search space may further contain references to UE-specific search spaces, and respective numerologies. A first search space may further provide a UE with scheduling information carrying an indication of a second additional search space with another numerology. The scheduling information may in particular indicate the numerology of the second additional search space. 
     The proposed solution can support multiple numerologies of fundamental parameters without placing an excessive load on a broadcast channel, so that a UE can quickly and unambiguously learn what numerologies are supported in different sub-band portions of a carrier. The solution is also forward compatible, so that new numerologies expressed e.g. by physical layer parameters and e.g. new channel and frame structure design can be put to use in sub-band portions of a carrier, even if they are not present in the first version or versions of a deployment, and the new channel and frame structure is developed in the future. By such an approach, once new channel and frame structures are developed, the old backwards-compatible sub-portion of the carrier can be reduced to a minimum serving only those remaining UEs that does not support the new channel and frame structure, and new sub-band solutions can be put to use in an efficient way. 
     An example of a broadcast channel is a PBCH carrying system information. Often, a PBCH is modelled to carry broadcast messages on a broadcast transport channel (BCH). i.e. the traffic on BCH is mapped on PBCH. 
     First, a UE acquires information about how and where to receive a broadcast channel. The information about how (numerology) and where (physical resources) to receive the broadcast channel can e.g. be based on the reception of synchronization information. 
     Reception of synchronization information provides some very basic information of the carrier cell structure and timing, and in one alternative, the numerology of the PBCH transmission is provided within the synchronization channel or channels that the UE acquires initially. For example, the UE may be required to test a few hypotheses of synchronization channel numerology, and based on the reception of the synchronization channel, the UE can deduce the numerology or set of numerologies that may apply to the reception of the broadcast channel. However, and alternatively, some or all parameters, i.e. numerology, defining where and how to receive the broadcast channel could be hard coded into the UE, e.g. based on some parameters agreed in a standard specification or the like; the parameters need not be configurable or variable during normal operation of the UE. 
     For example, it could be defined that the UE will use e.g. a sub-carrier spacing of 15 kHz and/or a specific slot format and/or cyclic prefix and/or specific location of the PBCH when reading the information carried on the PBCH. In an alternative, the sub-carrier spacing and other parameters dependent on the subcarrier spacing are defined and programmed into the UE, such that the parameters are dependent on the carrier frequency. For example, it could be defined or pre-agreed that a carrier implemented below a frequency f 1  has a sub-carrier spacing of sc 1  for PBCH, a carrier implemented between frequencies f 1  and f 2 , has sub-carrier spacing of sc 2  for PBCH, and so on. 
     The same or a similar approach may also apply to one or several of the following: the timing of the PBCH, i.e. its periodicity, the location of the PBCH on the frequency and time-domain placement, the resource blocks that carry PBCH, and the modulation and coding of the PBCH. 
     On the PBCH, the UE can now receive some very fundamental information of the system, i.e. system information. However, to avoid excessive load on the PBCH, which could occur if PBCH also carries numerology information for all sub-bands, the invention uses the following approach. The sub-band carrying PBCH will hereafter also be called control sub-band. 
     Information on PBCH may now include a reference to search spaces and/or carrier regions for receiving additional information, such as control channels and data. As used herein, the term “search spaces” also includes carrier regions. The BCH information may for example include a reference to a common search space and/or one or multiple additional search spaces. The additional search space may be common or UE-specific. The BCH information may further include information on the numerology to be used in the referenced search space or search spaces. The information on the numerology may, for example, provide a reference to a table of different numerologies, wherein the table identifies what numerology the UE should apply when decoding information on the search space or search spaces. Alternatively, the BCH data may include information on whether the search space or search spaces apply the same numerology as BCH, or if the numerology is different. Other information could also be provided, or the format could e.g. be the value of integer m in the expression 2 m ×15 kHz, to identify a specific numerology. The information regarding the additional search spaces may also include information about the location of the search space in the time-frequency resource grid. 
     The common search space may also be defined to have the same numerology as BCH, to further reduce the signaling on BCH. In the common search space, the UE may be scheduled to receive additional information about one or several additional search spaces or other information. 
     In such an embodiment, the information provided in information scheduled at the common search space may include a reference to one or several additional search spaces, in which case the additional search spaces may use different numerologies. Such information could be scheduled and received on a data region of a frame or subframe, wherein the data is scheduled by a radio network temporary identifier (RNTI) on the common search space. 
     A search space may refer to locations (which in LTE are called control channel elements) where a UE can expect to find downlink control channels (PDCCH) that are of relevance for the UE. A common search space is a search space that many, or even all. UEs on a carrier needs to monitor, at least intermittently. Such a common search space may carry e.g. scheduling of paging information (using a paging-RNTI in LTE), or further system information (scheduled by a system information-RNTI in LTE), or e.g. random access responses. In this common search space, the UE may be scheduled to receive information about additional search spaces. The information about additional search spaces may include information about the numerology of the additional search space. In one embodiment, this information is carried in system information mapped onto the data region of a frame, subframe or slot. 
     A schematic illustration of an embodiment is provided in  FIG.  3   . In  FIG.  3   , the time-relationship and size of different illustrated regions are only schematic. According to the embodiment, the BCH is transmitted from the BS and is received by the UE using a first numerology, numerology 1 . As illustrated, the BCH information may include a reference to a common search space. The BCH information may further include information as described above on the numerology of the common search space. In  FIG.  3   , the numerology of the common search space is the same as the numerology of the BCH, i.e. numerology 1  on sub-carrier region 1 . Next, the UE receives, in or associated with the common search space, information about an additional search space. In the illustration, the additional search space is now implemented using a second numerology, numerology 2  on sub-carrier region 2 .  FIG.  3    also includes a third search space, which is not assigned to this UE. For illustration purposes, it is shown that this third search space may implement a third numerology, numerology 3  on sub-carrier region 3 . 
     In the embodiment illustrated in  FIG.  3   , a reference to the additional, second search space is provided in the common search space. However, a reference to an additional, second search space may also be provided directly in the information carried on BCH, as illustrated in  FIG.  4   . 
     In  FIG.  4   , it is exemplified that also the common search space may implement a different numerology, numerology 2  on sub-carrier region 2 , than the numerology of the BCH, numerology 1  on sub-carrier region 1 . It should further be noted that all the illustrated regions (search spaces and BCH) may occur periodically, or even in every subframe or slot (not illustrated). The periodicity may be different for the relevant search spaces. 
     A benefit of providing information about the numerology of the additional search space or spaces from via the common search space is that the information can be provided on a shared channel, scheduled by assignments, such as downlink control information (DCI) on PDCCH, as explained below. The UE searches for (data) scheduling assignments on the common search space. When it identifies a scheduling assignment relating to an RNTI intended for this purpose, the UE finds an allocation of downlink resources, i.e., a scheduling command and corresponding scheduling of downlink data. For example, this data can be control information, e.g. identified as system information, carried on the data region of a frame, subframe or slot. The downlink data region may carry information about the additional search space and its numerology, as explained before or other information. This is illustrated in  FIG.  5   . 
     In one solution, the scheduling assignment is directed to a plurality of UEs, using an RNTI that is common to the plurality of UE&#39;s, such as a System Information RNTI (SI-RNTI). In another solution, the UE is directed to the additional search space using an assignment directed specifically to this UE, i.e. using e.g. the UEs Cell-RNTI (C-RNTI), wherein the C-RNTI is allocated to this UE. In this latter solution, the UE may first need to establish a connection to the network, by which it can receive such UE specific control information about the additional search space or spaces via dedicated signaling, such as Radio Resource Control (RRC) signaling. The latter approach may reduce the need for repetitive control information on the carrier, as UEs are assigned to receive the aforementioned control information only at times when specifically needed. 
     A network  4 , wherein embodiments described herein can be implemented is presented in  FIG.  1   . A UE 1 is wirelessly connectable to a BS 2. The BS 2 is connected to a core network (CN) 3. 
     A method, according to an embodiment, for enabling multiple numerologies in a network is presented with reference to  FIG.  6 A . The method is performed by a UE and comprises receiving S 110  system information in a first search space on a broadcast channel with a first numerology, determining S 120  a second search space from the received system information, and receiving S 130  further information in the second search space with a second numerology. 
     The first numerology may be different from the second numerology. 
     The broadcast channel may be a physical broadcast channel (PBCH). 
     The step of receiving may further comprises detecting system information. 
     The method may further comprise receiving S 100  synchronization information for a broadcast channel prior to the step of receiving S 110 . 
     The second numerology may be indicated in the received system information. 
     The second search space may be UE-specific. 
     The second search space may be a common search space. 
     The step of determining S 120  may further comprise determining a third search space having a third numerology. 
     A method for enabling multiple numerologies in a network is presented with reference to  FIG.  6 B . The method is performed by a BS and comprises sending S 210  system information in a first search space on a broadcast channel with a first numerology and sending S 220  further information in a second search space with a second numerology. 
     The method may further comprise sending S 200  synchronization information for a broadcast channel. 
     A UE for enabling multiple numerologies in a network is presented with reference to  FIG.  7   . The UE 1 comprises a processor  10 , and a computer program product  12 ,  13 . The computer program product stores instruction that, when executed by the processor, causes the UE to receive S 110  system information in a first search space on a broadcast channel with a first numerology, determine S 120  a second search space from the received system information, and to receive S 130  further information in the second search space with a second numerology. 
     A BS for enabling multiple numerologies in a network is presented with reference to  FIG.  8   . The BS 2 comprises a processor  20 , and a computer program product  22 ,  23 . The computer program product stores instruction that, when executed by the processor, causes the BS to send S 210  system information in a first search space on a broadcast channel with a first numerology, and to send S 220  further information in a second search space with a second numerology. 
     A UE for enabling multiple numerologies in a network is presented with reference to  FIG.  9   . The UE 1 comprises a communication manger  91  and a determination manager  90 . The communication manager is for receiving S 110  system information in a first search space on a broadcast channel with a first numerology, and for receiving S 130  further information in the second search space with a second numerology. The determination manager is for determining S 120  a second search space from the received system information. 
     A BS for enabling multiple numerologies in a network is presented with reference to  FIG.  10   . The BS 2 comprises a communication manager  101  for sending S 210  system information in a first search space on a broadcast channel with a first numerology, and for sending S 220  further information in a second search space with a second numerology. 
     A computer program  14 ,  15  for enabling multiple numerologies in a network is presented. The computer program comprises computer program code which, when run on a UE, causes the UE 1 to receive S 110  system information in a first search space on a broadcast channel with a first numerology, determine (S 120 ) a second search space from the received system information, and to receive S 130  further information in the second search space with a second numerology. 
     A computer program  24 ,  25  for enabling multiple numerologies in a network is presented. The computer program comprises computer program code which, when run on a BS, causes the BS 2 to send S 210  system information in a first search space on a broadcast channel with a first numerology, and to send S 220  further information in a second search space with a second numerology. 
     A computer program product  12 ,  13  ( FIG.  7   ),  22 ,  23  ( FIG.  8   ) comprising a computer program  14 ,  15  ( FIG.  7   ),  24 ,  25  ( FIG.  8   ) and a computer readable storage means on which the computer program  14 ,  15 ,  24 ,  25  is stored, is also presented. 
       FIG.  7    is a schematic diagram showing some components of the UE 1. The processor  10  may be provided using any combination of one or more of a suitable central processing unit, CPU, multiprocessor, microcontroller, digital signal processor. DSP, application specific integrated circuit etc., capable of executing software instructions of a computer program  14  stored in a memory. The memory can thus be considered to be or form part of the computer program product  12 . The processor  10  may be configured to execute methods described herein with reference to  FIG.  6 A . 
     The memory may be any combination of read and write memory. RAM, and read only memory, ROM. The memory may also comprise persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory. 
     A second computer program product  13  in the form of a data memory may also be provided, e.g. for reading and/or storing data during execution of software instructions in the processor  10 . The data memory can be any combination of read and write memory, RAM, and read only memory. ROM, and may also comprise persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory. The data memory may e.g. hold other software instructions  15 , to improve functionality for the UE 1. 
     The UE 1 may further comprise an input/output (I/O) interface  11  including e.g. a user interface. The WD  1  may further comprise a receiver configured to receive signaling from other nodes, and a transmitter configured to transmit signaling to other nodes (not illustrated). Other components of the UE 1 are omitted in order not to obscure the concepts presented herein. 
       FIG.  9    is a schematic diagram showing functional blocks of the UE 1. The modules may be implemented as only software instructions such as a computer program executing in the cache server or only hardware, such as application specific integrated circuits, field programmable gate arrays, discrete logical components, transceivers, etc. or as a combination thereof. In an alternative embodiment, some of the functional blocks may be implemented by software and other by hardware. The modules correspond to the steps in the methods illustrated in  FIG.  6 A , comprising a determination manager unit  90  and a communication manager unit  91 . In the embodiments where one or more of the modules are implemented by a computer program, it shall be understood that these modules do not necessarily correspond to process modules but can be written as instructions according to a programming language in which they would be implemented, since some programming languages do not typically contain process modules. 
     The determination manger  90  is for enabling multiple numerologies in a network. This module corresponds to the determine step S 1210  of  FIG.  6 A . This module can e.g. be implemented by the processor  10  of  FIG.  7   , when running the computer program. 
     The communication manger  91  is for enabling multiple numerologies in a network. This module corresponds to the receive step S 100 , the receive step S 110  and the receive step S 130  of  FIG.  6 A . This module can e.g. be implemented by the processor  10  of  FIG.  7   , when running the computer program. 
       FIG.  8    is a schematic diagram showing some components of the base station  2 . A processor  20  may be provided using any combination of one or more of a suitable central processing unit. CPU, multiprocessor, microcontroller, digital signal processor, DSP, application specific integrated circuit etc., capable of executing software instructions of a computer program  24  stored in a memory. The memory can thus be considered to be or form part of the computer program product  22 . The processor  20  may be configured to execute methods described herein with reference to  FIG.  6 B . 
     The memory may be any combination of read and write memory, RAM, and read only memory, ROM. The memory may also comprise persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory. 
     A second computer program product  23  in the form of a data memory may also be provided, e.g. for reading and/or storing data during execution of software instructions in the processor  20 . The data memory can be any combination of read and write memory, RAM, and read only memory. ROM, and may also comprise persistent storage, which, for example, can be any single one or combination of magnetic memory, optical memory, solid state memory or even remotely mounted memory. The data memory may e.g. hold other software instructions  25 , to improve functionality for the BS 2. 
     The BS 2 may further comprise an input/output, I/O, interface  21  including e.g. a user interface. The BS 2 may further comprise a receiver configured to receive signaling from other nodes, and a transmitter configured to transmit signaling to other nodes (not illustrated). Other components of the BS 2 are omitted in order not to obscure the concepts presented herein. 
       FIG.  10    is a schematic diagram showing functional blocks of the BS 2. The modules may be implemented as only software instructions such as a computer program executing in the cache server or only hardware, such as application-specific integrated circuits, field programmable gate arrays, discrete logical components, transceivers, etc. or as a combination thereof. In an alternative embodiment, some of the functional blocks may be implemented by software and other by hardware. The modules correspond to the steps in the methods illustrated in  FIG.  6 B , comprising a communication manager unit  101 . In the embodiments where one or more of the modules are implemented by a computer program, it shall be understood that these modules do not necessarily correspond to process modules but can be written as instructions according to a programming language in which they would be implemented, since some programming languages do not typically contain process modules. 
     The communication manger  101  is for enabling multiple numerologies in a network. This module corresponds to the send step S 200 , the send step S 210 , and the send step S 220  of  FIG.  6 B . This module can e.g. be implemented by the processor  20  of  FIG.  8   , when running the computer program. 
     The invention has mainly been described above with reference to a few embodiments. However, as is readily appreciated by a person skilled in the art, other embodiments than the ones disclosed above are equally possible within the scope of the invention, as defined by the appended patent claims.