DE102017215703B4 - Establishment, system, and procedure for advertising the capability of an establishment - Google Patents

Abstract

Method comprising:
on a user device (105):
Determining (315) a number of available slots for advertising carrier aggregation (CA) combinations to a network;
Determining (335) an order of priority for a plurality of bands that are part of the CA combinations;
Determining (340) a list of the CA combinations based on the order of priority; and
Transmitting (345) a portion of the list of CA combinations to the network in priority order, the portion corresponding to the number of seats available;
wherein determining (335) the order of priority comprises:
Determining a timing parameter for each of the bands based on how recently the user device occupied each of the bands, with priority given to the bands that were most recently occupied.

Description

PRIORITY INFORMATION / RECORDING BY REFERENCE

This application claims priority from the US provisional application 62 / 384,467 entitled "Device, System, and Method for Advertising Device Capability," which was filed on September 7, 2016, and which is incorporated herein by reference in its entirety.

BACKGROUND INFORMATION

A user equipment (BG) can be configured with a variety of different capabilities. For example, the BG may be able to connect to a wireless network. In particular, the BG can connect to a Long Term Evolution (LTE) network. During the connection to the LTE network, the BG can use further network capabilities. For example, the BG can use a carrier aggregation (CA) functionality in which a primary component carrier (PCC) and at least one secondary component carrier (SCC) are used to communicate data over the various LTE bands. In order to use the CA functionality, LTE standards require the BG to advertise the combinations of PCC and SCCs supported by the BG. However, with an increasing number of LTE bands and a limited number of combinations that can be advertised, the advertising process is inefficient, especially since a double CA arrangement (1 PCC and 1 SCC) precedes a triple CA arrangement (1 PCC and 2 SCCs), although the triple CA arrangement may be preferred.

In addition, the capabilities of the BG can be requested from the LTE network. However, the uplink (UL) grant size for the BG to transmit the capability information has limited space. This capability information can include the above CA advertisements and measurement information for the various LTE bands. These measurements can be provided so that the LTE network can identify the optimal CA arrangement for use by the BG. However, other capability information may also be included in the UL grant. For example, complete measurement capability information can be provided. The seamless measurement capability includes the available bands via LTE bands, various RAT bands and the CA combinations. Thus, the gapless metrology information can take up a significant portion of the limited space of the UL grant which is indicative of the BG's capabilities.

If the UL grant is too small to provide all of the BG capability information, then this can lead to various errors and unsatisfactory user experiences, such as network timeouts and attach errors.

US 20150327269 A1 describes that in order to transmit capability information of a user device to an evolved Node B (eNB), the user device can generate a user device capability information message including the capability information of the user device and transmit the generated user device capability information message to the eNB. Here, the capability information of the user equipment can include at least one band combination supported by the user equipment and whether the time division duplex-frequency duplex carrier aggregation is supported for the band combination.

Further methods and devices are described in US 20150173094 A1 , US 20130114508 A1 , US 20130064162 A1 , EP 3270650 A1 and EP 3276868 A1 described.

SUMMARY

The invention is defined by the independent claims. Preferred embodiments are described by the dependent claims. Procedure performed by a user device. The method includes determining a number of available locations to advertise carrier aggregation (CA) combinations to a network, determining an order of priority for a plurality of bands that are part of the CA combinations, determining a list of the CA combinations Based on the order of priority and transferring a portion of the list of CA combinations in the order of priority to the network, the portion corresponding to the number of digits available.

A user device having a transceiver configured to connect the user device to a network, the user device and the network being configured for carrier aggregation (CA) functionality. The user equipment also having a processor to determine a number of available locations to advertise CA combinations to the network, the processor determining an order of priority for a plurality of Long Term Evolution (LTE) bands that are part of the CA. -Combinations are where the processor determines a list of CA combinations based on the order of priority, the transceiver sending a portion of the list of CA combinations in the order of priority to the network transfers, where the segment corresponds to the number of available positions.

Integrated circuit with switching logic for determining a number of available locations for advertising carrier aggregation (CA) combinations to a network, switching logic for determining a priority order for a plurality of bands that are part of the CA combinations, switching logic for determining one List of CA combinations based on the order of priority and switching logic for determining a portion of the list of CA combinations in the order of priority to be transmitted to the network, the portion corresponding to the number of available locations.

Another method performed by a user device that includes a transceiver configured to communicate with a network. The method includes determining whether the transceiver is configured to perform predetermined types of gapless measurements, setting a corresponding indicator for each type of gapless measurement based on whether the transceiver is capable of performing the type of gapless measurement in response to a Network request of a capability of the user device to carry out, transmit a message to the network including the corresponding indicators and, in response to a subsequent network request of the capability of the user device, to transmit another message to the network that omits the appropriate indicators for the types of gapless measurements, which the transceiver is unable to perform.

User device with a transceiver configured to communicate on a network. The user device also has a processor that determines whether the transceiver is configured to perform predetermined types of gapless measurements and to set a corresponding indicator for each type of gapless measurement based on whether the transceiver is capable of the type of gapless measurement perform. In response to a network request for a capability of the user equipment, the transceiver transmits a message to the network, including the corresponding indicators, and, in response to a subsequent network request for the capability of the user equipment, transmits a further message to the network containing the appropriate indicators for the types of gapless Omits measurements that the transceiver is unable to perform.

Integrated circuit with switching logic to determine whether a transceiver is configured to perform specified types of gapless measurements, switching logic to set a corresponding indicator for each type of gapless measurement based on whether the transceiver is able to perform the type perform the gapless measurement, switching logic for generating a message in response to a network request for a capability of a user device, the message including the appropriate indicators and switching logic to generate a further message in response to a subsequent network request for the capability of the user device, the further Message that omits appropriate indicators for the types of gapless measurements that the transceiver is unable to perform.

Figure list

• 1 Figure 12 shows a system in which a user device modifies the display of network capabilities in accordance with various embodiments described herein.
• 2 shows an example of carrier aggregation.
• 3 FIG. 10 shows a method for advertising carrier aggregation functionality in accordance with various exemplary embodiments described herein.
• 4th shows a table listing the prioritized carrier aggregation combinations for advertising according to the exemplary embodiments.
• 5 FIG. 4 shows a method for generating indicators associated with a gapless measurement, according to various exemplary embodiments described herein.

DETAILED DESCRIPTION

The exemplary embodiments can be further understood with reference to the following description and the appended drawings, wherein like elements are denoted by the same reference numerals. The exemplary embodiments relate to a device, a system and a method for advertising capability of a user equipment (BG) to a network to which the BG is connected. In particular, the network can be a Long Term Evolution (LTE) network and the network capabilities that are advertised can generally relate to the BG capabilities and also more particularly to a carrier aggregation (CA) capability, the CA functionality can contain a primary serving cell (PCell) and at least one secondary serving cell (SCell). The exemplary embodiments provide a first mechanism for the BG for which the CA functionality is activated with a network in order to advertise selected CA combinations that efficiently indicate the CA capability to the network. The embodiments provide a second mechanism for the BG to convert transmit an initial indication of BG skills, which enables subsequent skill information to be transmitted in an efficient manner.

The BG can be linked to a network component that serves as a PCell. In an LTE network, the network component can be an Evolved Node B (eNB). The PCell can control the manner in which the data is exchanged with the BG, such as determining whether uplink and downlink grants are given for the BG. The PCell can also control the mechanism used in exchanging data, particularly how data is transmitted to and received from the BG. If the BG is CA-capable, CA functionality enables the PCell and another SCell to combine bandwidths in order to exchange data with the BG. The SCell can also be configured and activated by the eNB based on throughput requirements. Thus, in the case of CA, the PCell can provide a first section of a total bandwidth for data to be exchanged, while the SCell can provide a second section of the total bandwidth. A PCell and a single SCell can be referred to as a double CA combination (two bearers) and can be used to provide all of the available bandwidth. An additional SCell can be integrated to further increase the total available bandwidth for data to be exchanged with the BG. One PCell and two SCells can be referred to as a triple CA combination and can be used to provide all of the available bandwidth. One PCell and three SCells can be referred to as a quadruple CA combination and can be used to provide all of the available bandwidth. The embodiments are described in terms of double, triple and quadruple CA combinations. However, those skilled in the art will understand that the exemplary embodiments can be modified for the PCell and any number of SCells to be used in the CA functionality.

Those skilled in the art will understand that the CA functionality is controlled by the eNB, which serves as the PCell for the BG. For example, upon detection that the BG is CA-capable and a transmission rate to the BG is below a maximum possible transmission rate, the eNB can activate the CA functionality. The SCells can be selected and used for any data exchange. When selecting the SCells, the BG can carry out measurements of the LTE bands in order to determine the quality of the CA combinations. The LTE specification, Release 11 TS 36.331 (e.g. 3GPP TS 36.331 V.11.0.0 and higher) requires that the BG advertise all supported CA combinations. In this way, the BG can carry out the measurements for all available CA combinations and advertise the corresponding qualities. The LTE specification also states that the BG is only a maximum 128 May advertise CA combinations. So there is a limit of 128 CA combinations for the total number of CA combinations in an existing CA container in which the BG is allowed to advertise. In current implementations, the BG can first advertise all available duplicate CA combinations. If the number of all available duplicate CA combinations is less than the maximum limit, then the triple CA combinations and then the quadruple CA combinations can be advertised if there is still space for advertising. However, there may be cases where the number of duplicate CA combinations alone is more than 128 amounts to. For example, depending on the provider, 13 LTE bands may be available. Accordingly, the number of duplicate CA combinations can be up to 169. There is a risk that the BG cannot advertise the triple or quadruple CA combinations to the network even though the triple or quadruple CA combinations are supported by both the BG and the PCell. Indeed, there is also a risk that the BG may not be able to advertise capabilities for duplicate CA combinations of higher quality.

1 shows a system 100 , in which a BG modifies the display of network capabilities in accordance with various embodiments described herein. The system 100 includes a BG 105 and a variety of eNBs 130 , 135 , 140 . As discussed above, the BG 105 deal with one of the eNBs 130-140 such as the eNB 130 link to connect to the network that the eNB 130 such as an LTE network. The BG 105 and the eNBs 130-140 can also include the CA functionality provided by the eNB 130 can be activated and controlled. Since the BG 105 with the eNB 130 is linked, the eNB 130 provide the CA configuration for component carriers used by the BG 105 should be used in which the eNB 130 the PCell can be and the eNBs 135 , 140 can serve as the SCells.

The BG 105 can be any electronic component that is configured to communicate with a network through the eNB 130 connect to. For example, the BG 105 be a portable device such as a cell phone, smartphone, tablet, phablet, laptop, wearable device, etc. In another example, the BG 105 be a stationary device, such as a desktop terminal. The BG 105 can also operate on a variety of different frequencies or channels (ie, on a range of continuous frequencies) work. Accordingly, the BG 105 Components that enable different wireless access technologies. As in 1 shown, the BG 105 a processor 110 , a memory array 115 and a transceiver 120 include. However, the BG 105 also include other components such as a display device, an input / output (I / O) device, and other components such as a portable power supply, audio I / O device, etc.

The processor 110 can be configured to accommodate a variety of applications of the BG 105 to execute. For example, the applications may include a web browser when passing through the transceiver 120 are connected to a communication network. Accordingly, data can be exchanged with the network. In particular, the data can be exchanged using the CA functionality in order to increase the rate at which the data is exchanged. In another example, the applications can be a CA advertising application 125 that is configured to determine how the CA combinations are advertised to the network. As will be described in greater detail below, the CA advertising application 125 first determine the characteristics of the LTE specification supported by PCell. The CA advertising application 125 can then specify which of the CA combinations should be advertised if there is still an opportunity to advertise. In another example, the applications can be a complete measurement application (GM application) 127 configured to set indicators for various types of GMs that the BG is currently configured to perform.

Note that the implementation of the above-mentioned applications as an application (e.g., a program) required by the processor 110 is carried out, is only exemplary. The applications can also be used as components of one or more multifunctional programs, a separate integrated component of the BG 105 or be a modular component that comes with the BG 105 is coupled, for example an integrated circuit with or without firmware. In addition, with some BGs the one for the processor 110 functionality described on two processors, a baseband processor and an application processor, divided. The exemplary embodiments can be implemented in any of these or other configurations of a UE.

The storage arrangement 115 may be a hardware component configured to store data related to operations performed by the BG 105 are executed. In particular, the memory arrangement 115 Save measurements or properties associated with different CA combinations.

Using the CA functionality, the eNB 130 serve as the PCell while the eNBs 135 , 140 can serve as at least one of the SCells. 2 shows an example of carrier aggregation. As in 2 As shown, the PCell can provide a first component carrier of 10 MHz, which is a primary component carrier (PCC) that operates on a first LTE band, while the SCell can provide a second component carrier of 10 MHz that represents the secondary component carrier (SCC) that works on a second LTE band. 2 also shows a type of carrier aggregation. In particular shows 2 the two component carriers in an intraband carrier aggregation with continuous component carriers. However, it will be apparent to a person skilled in the art that other types of carrier aggregation can also be used, such as, for example, intra-band carrier aggregation with discontinuous component carriers, inter-band carrier aggregation, or any combination of these three types. Furthermore, it will be obvious to a person skilled in the art that other bandwidths can be used, such as 1.4, 3, 5, 15 or 20 MHz, and usually a maximum of five component carriers can be aggregated. Again, if only one SCell is used, a double CA combination arrangement can be used, and if two SCells are used a triple CA combination arrangement can be used. As in 2 shown, two component carriers with a bandwidth of 10 MHz each can be combined to a total bandwidth of 20 MHz. In a specific example, the standard LTE-Advanced device that supports 20 MHz carrier aggregation can achieve a downlink (“DL”) throughput of 100 Mbps (when the maximum of five component carriers are aggregated). In another example, a theoretical maximum of approximately 150 Mbps can be achieved, such as when only two 10 + 10 carriers are aggregated.

It should be noted that in the system 100 network shown is only exemplary. For example is the number of eNBs 130-140 that are in the communicative area of the BG 105 may be more or less than three. It will be apparent to those skilled in the art that there can be any number of other types of networks which are also located in the communicative area of the BG 105 and that the BG 105 can also be configured to connect to them. That is, the BG 105 can also be connected to different wireless access technologies (radio access technologies, RATs). For example, the system 100 also include an old wireless access network (e.g. CDMA, GSM, etc.), a wireless local area network, a WiFi network, etc. When configured for such a capability, the CA functionality itself can be used between other types of networks. However, for exemplary purposes, the CA functionality is described herein in relation to the LTE network and the component carriers are owned by the eNBs 130-140 provided. It should be understood, however, that the exemplary embodiments can be used in connection with any network that implements CA or analog functionality.

As described above, the advertising associated with CA combinations can be done so that the CA functionality that can be used is a limited operation. In this example, only up to 128 different CA combinations can be advertised to the network even if the total number of CA combinations far exceeds this limit. It should be noted that LTE specification Release 11 TS 36.331 also provides another feature that 256 CA combinations supported in addition to the existing CA combinations. These additional 256 However, CA combinations are only supported if the network with which the BG 105 is connected, supports the said feature. The feature may be a requested frequency band (RFB) feature in which the network displays a set of LTE bands used in the advertising of the CA combination by the BG 105 should be prioritized. In particular, the set of LTE bands can be used for the double CA combination arrangements. The BG thus prioritizes 105 the duplicate CA combinations that contain the requested LTE bands. However, if the network does not support this RFB feature and the BG 105 is requested to advertise the CA combinations, the BG 105 Advertise all available supported duplicate CA combinations, whereby no priority is assigned to an order of the duplicate CA combinations.

Given the way in which CA combinations are used by the BG 105 are advertised, the embodiments provide a first mechanism in which a BG-based solution is provided in which the BG is able to find the most relevant CA combinations within the maximum limit of 128 to advertise. Indeed, the first mechanism can override certain restrictions, such as advertising all duplicate CA combinations before advertising any triple CA combinations. Thus, the most relevant CA combinations can be advertised using the first mechanism of the embodiments, and may include duplicate CA combinations, triple CA combinations, and quadruple CA combinations, although not all duplicate CA combinations are advertised. In this way, the CA advertising application 125 perform a set of operations to properly advertise CA combinations. Since the first mechanism according to the exemplary embodiments is a BG-based solution, the operations of the network can remain unchanged and the network can continue to work under defined parameters. In particular, if properly configured, the network can continue to use the RFB feature and the first mechanism of the embodiments can incorporate the RFB feature to provide to the BG 105 to enable the RFB feature to be responded appropriately when invoked by the network.

The CA advertising application 125 can first determine whether the network is using the RFB feature. For example, the network may request that the BG 105 advertises the CA combinations that the BG 105 can use. Without the RFB feature, the BG 105 select the CA combinations for advertising. In this way, the BG 105 without the RFB feature up to the maximum 128 Advertise CA combinations. Using the first mechanism of the embodiments, the BG 105 generate a list of LTE bands based on an order of priority given by the CA advertising application 125 is determined. In an exemplary embodiment, the BG 105 Prioritize the CA combinations in the order of quadruple CA combinations, triple CA combinations, and then double CA combinations. This type of prioritization prioritizes higher throughputs for the BG based on the fact that using four carriers generally achieves higher throughput than three carriers or two carriers. However, other types of prioritization of the CA combinations can also be used. Since this process LTE bands through the BG 105 selects the LTE bands used by the BG 105 are selected, referred to as UE-RFBs (user equipment requested frequency bands).

The priority on the basis of which the BG 105 The LTE bands can also be based on a variety of factors. For example, the CA advertising application 125 prioritize a time parameter, the LTE band being assigned a highest priority, that of the BG 105 last occupied. The CA advertising application 125 can then prioritize a neighbor parameter, with the next highest priority being given to the neighbors of the LTE band that the BG 105 last occupied is assigned. Of the Neighbor parameter can be based on the SIB-5 inter-frequency neighbor information. The CA advertising application 125 can further prioritize the LTE bands again using the time parameters, the next higher priority being assigned to a second, most recently occupied LTE band. The CA advertising application 125 can then use the neighbor parameter to prioritize the neighbors of the second most recently occupied LTE bands. In this way, the CA advertising application 125 Prioritize the LTE bands based on the time parameter and the neighboring parameter. Furthermore, the CA advertising application 125 also update the order of priority based on the knowledge of the provision of cellular bearers collected through historical data harvesting. Depending on the provider, there can also be up to 16 LTE bands here. This list can thus be continued up to a maximum of 16 LTE bands for the UE RFBs.

In an exemplary list generated using the first mechanism of the embodiments, the first set of CA combinations to be advertised may be all four-fold CA combinations that represent the highest priority LTE band in the UE RFBs as PCC, while the three SCCs can be any LTE band in the UE RFBs (with higher priority LTE bands being assigned higher priority in the UE RFBs). As mentioned above, the LTE band with the highest priority can be the last used LTE band. The second set of CA combinations to be advertised can be any triple CA combinations that have the LTE band with the highest priority in the UE RFBs as PCC, while the other two SCCs have any LTE band in the UE RFBs can be. The third set of CA combinations to be advertised can include all duplicate CA combinations that have the LTE band with the highest priority in the UE RFBs as PCC, while the SCCs use any LTE band in the UE RFBs can be. The fourth set of CA combinations can be all other CA combinations that contain as the only requirement the LTE band with the highest priority in the UE RFBs as PCC. That is, in the example of the fourth set of CA combinations, there is no requirement that the SCCs be included in the UE RFBs. It should be noted that an example of the UE RFB selection and the corresponding CA combinations is given below with reference to FIG 4th will be provided.

The exemplary list can be continued so that the fifth set of CA combinations to be advertised can be all four-fold CA combinations that have the second highest priority LTE band in the UE RFBs as PCC, while the three SCCs can be any LTE band in the UE RFBs (with higher priority LTE bands being assigned higher priority in the UE RFBs). As mentioned above, the LTE band with the second highest priority can be a neighbor of the last occupied LTE band. The sixth set of CA combinations to be advertised can be any triple CA combinations that have the LTE band with second highest priority in the UE RFBs as PCC, while the other two SCCs have any LTE band in the UE RFBs can be. The seventh set of CA combinations to be advertised can include all duplicate CA combinations that have the LTE band with second highest priority in the UE RFBs as PCC, while the SCCs have any LTE band in the UE RFBs can be. The eighth set of CA combinations to be advertised can be all other CA combinations that contain as the only requirement the LTE band with the second highest priority in the UE RFBs as PCC.

In this way the exemplary list can be continued until 128 different CA combinations can be advertised to the network. Using this methodology, the BG 105 configured to advertise the most relevant CA combinations for use by the network. That is, less relevant CA combinations that have a low probability or a near zero probability of being used can be eliminated and not advertised. This significantly increases the likelihood that the more relevant CA combinations will be advertised.

It should be noted that the list of UE RFBs can depend on a variety of factors. For example, the list can be based on the current factors identified by the BG 105 be experienced, dynamic or different. Thus, the BG 105 store a variety of UE RFBs that can be used depending on these factors. For example, the BG 105 dynamically modify the UE RFBs when it is aware that a particular LTE band may not be available. Thus, the LTE band can be removed from the UE RFBs when the list of relevant CA combinations is created. In another example, the factor can be a location. If the BG 105 is arranged at a first location, then the BG 105 use an initial list of UE RFBs. If the BG 105 however, is located at a second location (e.g. at a substantial distance from the first location), then the BG 105 use a second list of UE RFBs that is different from the first list of UE RFBs. In fact, while the BG 105 connected to the network. As the list of UE RFBs is increased by this movement can change (e.g. a new neighbor is added, an old neighbor is deleted, etc.), the BG 105 set a flag, for example in a tracking area update. When the network does a tracking area update for the BG 105 initiated, the flag can indicate that the BG 105 should update the CA combinations to be advertised. Accordingly, the BG 105 Advertise the LTE bands that are prioritized in the new, updated or different UE RFBs.

The above process of populating the relevant CA combinations using the first mechanism of the embodiments relates to when the network does not impose criteria and the BG 105 Everyone 128 Places in the available CA combination list. However, the network can be included as part of the RFB feature mentioned above, as described in the LTE specification Release 11 TS 36,331 is defined, include selected LTE bands in the requirement. As used herein, the LTE bands selected by the network in the RFB feature are referred to as NW RFBs.

If the network is configured with the RFB feature and the NW RFBs to the BG 105 transfers can also use the additional 256 CA combinations are used. Since the network RFB feature can be a high-level feature, the BG 105 respond to the advertising request by first advertising the CA combinations that satisfy the NW-RFBs. For example, the BG 105 determine all CA combinations that contain the NW-RFBs, ie the CA combinations currently used by the BG 105 supported and also included in the list of NW-RFBs provided by the BG 105 was received. After the list of supported CA combinations that correspond to the NW-RFBs has been determined, the CA advertising application can 125 determine if it's in the 128 there are any remaining spaces available for the CA combinations. For example, the NW-RFBs can only require 40 CA combinations to be advertised. This means that 88 spaces can still be available that can be used for advertising further CA combinations. In this scenario, if at least one available space is determined after using the NW RFBs, the first mechanism of the embodiments can be used again to fill the remaining available spaces. Thus, a substantially similar process to that described above can be used. It should be noted that any redundant CA combination of those connected to the NW RFBs can be omitted from the UE RFB analysis.

3 shows a procedure 300 for advertising a carrier aggregation functionality according to the exemplary embodiments. The procedure 300 may refer to the first mechanism of the embodiments in which the BG 105 determines the CA combinations that are to be advertised on the basis of predetermined criteria. As discussed above, CA combination advertising can be initiated as a network operation. After responding to requests from the network, the BG 105 however, select the CA combinations to be advertised if there is space for the advertising according to the requests from the network. Thus the procedure 300 from the BG 105 carried out and the procedure 300 will be related to the system 100 from 1 described.

As noted above, an example of the first mechanism will also be described. The example is related to the procedure 300 to be discribed. The example is in 4th which shows a table 400 listing the prioritized carrier aggregation combinations for advertising according to the exemplary embodiments. Initially it can be assumed that the BG 105 is in a specific area for which table 400 can be used. As shown, there will be a location 405 for table 400 to be used while the BG 105 at the location 405 is located. If the BG 105 however, if it is in a different location, another table can be stored and used.

In 305 determines the BG 105 the characteristics used by the network with which the BG 105 connected. Although there can be any number of features that the network may or may not support, the procedure will 300 in relation to the features of the LTE Specification Release 11. In particular, the feature of the LTE specification Release 11 can be the RFB feature, in which NW-RFBs from the network in an advertising request to the BG 105 to be selected. Thus, at 310, the BG determines 105 whether the RFB feature is supported by the network. If the RFB feature is not supported by the network, the BG sets 105 the procedure 300 until 315 away. In 315 determines the BG 105 the number of CA combinations available that can be advertised. Without requests from the network, the BG 105 determine that full 128 Places for advertising CA combinations are available.

When returning to 310, if the RFB function is supported, the BG sets 105 the procedure 300 until 320 away. In 320 receives the BG 105 the requested LTE bands from the network. That is, the NW-RFBs are off the network receive. Based on the NW-RFBs, the BG generates 105 in 325 the advertisement corresponding to the CA combinations containing the NW-RFBs. In 330 determines the BG 105 whether there is still space to advertise further CA combinations. As mentioned above, the BG 105 up to 384 Advertise CA combinations ( 128 CA combinations and others 256 Combinations) if the RFB feature is supported by the network (otherwise 128 CA combinations if the RFB feature is not supported by the network). It should be noted that the number of advertising slots available is exemplary only and is based on current LTE standards, the number may change over time as LTE standards evolve, and other types of networks may have different numbers of advertising slots to use. The exemplary embodiments are not limited to any particular number of advertising spaces and can be implemented on networks with any number of advertising spaces. If the CA combinations with the NW-RFBs use up all of the available spaces, the BG sets 105 the procedure 300 until 340 away. In 345 transmits the BG 105 the advertisement to the network, which only contains the CA combinations based on the NW-RFBs. However, if at least one space is available for a further CA combination, the BG sets 105 the procedure 300 until 315 to determine the number of seats available.

In 335 determines the BG 105 an order of priority for the types of CA combinations. That is, the UE RFBs can be determined. For example, an LTE band with the highest priority can be a most recently used LTE band. An LTE band with the second highest priority can be a neighbor of the LTE band with the highest priority. An LTE band with the third highest priority can be the next most recently occupied LTE band. An LTE band with the fourth highest priority can be a neighbor of the next most recently occupied LTE band. This priority list can be continued until all LTE bands are listed. In 340 can the BG 105 generate the advertisement for the CA combinations in which the UE RFBs may be included after any NW RFB. In 345 transfers the BG 105 the advertisement to the network.

In a specific example in which the UE RFBs are determined and the CA combinations are also determined, the table 400 shows when the BG 105 at the location 405 is located (e.g. Zone A) in which the UE RFBs with a sequence 415 prioritized as LTE bands 7, 4, 12, 1 and 13. As described above, the order can be 415 Prioritize the LTE band with an earliest timing parameter, followed by the LTE band (s) identified as being neighbors of the LTE band with the highest priority, followed by the LTE band with a next earliest timing parameter Parameters, followed by the LTE band (s) that are identified as neighbors of the LTE band with the next highest priority, and continue this sequence. For example, the LTE band 7 can represent an LTE band with the highest priority. In particular, the LTE band 7 can be the last LTE band that the BG 105 has occupied. Thus, LTE band 7 can be the first UE RFB in the order 415 be. LTE bands 4 and 12 can represent neighboring LTE bands of LTE band 7. Accordingly, the UE RFBs can use LTE bands 4 and 12 second and third in order 415 prioritize. LTE band 1 can be an LTE band with the next higher priority based on the timing parameter. Thus, the LTE band 1 can be the fourth UE RFB in the order 415 be. Finally, the LTE band 13 can be a neighboring LTE band of the LTE band 1. Accordingly, the LTE band 13 can be the fifth UE RFB in the order 415 be.

For example purposes, the table 400 may refer to when the provider 13 uses different LTE bands. However, those skilled in the art will understand that the provider can use any number of LTE bands. Those skilled in the art will understand how the exemplary embodiments would have to be modified in order to accommodate more or less different available LTE bands. It should be noted that the use of a table to store the various CA combinations is only an example. The BG 105 can save the CA combinations in any way.

Based on the UE RFBs 410 with the order 415 the table 400 can be determined which the CA combination priority 420 illustrated. The CA combination priority 420 can be read from left to right and top to bottom as from highest to lowest priority. The CA combination priority 420 can be arranged to list a full set of CA combinations for a selected PCC. As described above, the CA combinations can be prioritized with the first mechanism by first selecting the BG RFB with the highest priority as the PCC. Thus the first selected PCC is 425 the LTE band 7.

Using the first selected PCC 425 as LTE band 7, table 400 illustrates the full set of prioritized CA combinations. As described above, a first prioritized set of CA combinations 430 be the four-fold CA combinations where the UE-RFB with the highest priority is the PCC and any UE-RFBs are used as SCCs. For example, the CA combination of LTE band 7 (PCC) and LTE bands 4, 12 and 1 (SCCs) the four-fold CA combination with the highest priority, followed by LTE band 7 (PCC) with LTE bands 4, 12 and 13 (SCCs), LTE -Band 7 (PCC) with LTE bands 4.1 and 13 (SCCs) and LTE band 7 (PCC) with LTE bands 12.1 and 13 (SCCs). A second prioritized set of CA combinations 435 can be the triple CA combinations where the highest priority UE RFBs are the PCC and any UE RFBs are used as SCCs. For example, the CA combination of LTE band 7 (PCC) and LTE bands 4 and 12 (SCCs) may be the CA combination with the highest priority in this set, followed by LTE band 7 (PCC) with LTE bands 4 and 1 (SCCs), LTE band 7 (PCC) with LTE bands 4 and 13 (SCCs) etc. A third prioritized set of CA combinations 440 can be the duplicate CA combinations where the UE-RFB with the highest priority is the PCC and any UE-RFB is used as SCCs. For example, the CA combination of LTE band 7 (PCC) and LTE band 4 (SCC) can be the CA combination with the highest priority, followed by LTE band 7 (PCC) with LTE band 12 (SCC), LTE band 7 (PCC) with LTE band 1 (SCC) and LTE band 7 (PCC) with LTE band 13 (SCC).

A fourth prioritized set of CA combinations 445 can be the four-fold CA combinations in which the UE-RFB with the highest priority is the PCC and any other LTE bands (non-UE-RFB) are used as SCCs. For example, the four-fold CA combination of LTE band 7 (PCC) with combinations of LTE bands 2, 3, 5, 6, 8, 9, 10 and 11 (SCCs) can be listed here. It should be noted that due to space constraints in the figure, not all four-fold CA combinations are boxed 445 are listed. Those skilled in the art are aware of the remaining possible four-fold CA combinations that are not expressly listed. A fifth prioritized set of CA combinations 450 can be the triple CA combinations in which the UE-RFB with the highest priority is the PCC and any other LTE bands (non-UE-RFB) are used as SCCs. For example, the triple CA combination of LTE band 7 (PCC) with combinations of LTE bands 2, 3, 5, 6, 8, 9, 10 and 11 (SCCs) can be listed here. A sixth prioritized set of CA combinations 455 can be the double CA combinations where the UE-RFB with the highest priority is the PCC and any other LTE band (non-UE-RFB) is used as SCCs. For example, the CA combination of LTE band 7 with LTE bands 2, 3, 5, 6, 8, 9, 10 and 11 can be listed here. In this way, the CA combinations for LTE band 7 can be listed.

Table 400 also illustrates more CA combinations based on order 415 the UE RFB priority 410 . Since the CA combinations are prioritized with the first mechanism, the second is selected PCC 460 the LTE band 4. Thus, the set of CA combinations 465 List the quadruple CA combinations, with LTE band 4 being the PCC and the other UE RFBs being the SCCs. The set of CA combinations 470 can list the triple CA combinations with the LTE band 4 being the PCC and the other UE RFBs being the SCCs. The set of CA combinations 475 can list the duplicate CA combinations, where the LTE band 4 is the PCC and one of the other UE RFBs is the SCCs. The set of combinations 480 can list the quadruple CA combinations, where LTE band 4 is the PCC and the other LTE bands (non-UE RFBs) are the SCCs. The set of combinations 485 can list the triple CA combinations, with the LTE band 4 being the PCC and the other LTE bands being the SCCs. The set of combinations 490 can list the duplicate CA combinations, where LTE band 4 is the PCC and one of the other LTE bands (non-UE RFBs) is the SCCs.

The table 400 can further be generated with the next UE-RFB in the sequence 415 is selected to determine the CA combinations. Thus, the third selected PCC is LTE band 12. Table 400 can list the CA combinations for LTE band 12 as PCC in the same way as described above for LTE bands 7 and 4. Similarly, the same process can be repeated for the remaining UE RFB bands 1 and 13 to complete the table 400.

It should also be noted that the BG 105 using table 400 may be able to use all LTE bands and CA combinations thereof. Thus, the above description lists every possible combination for the various CA combinations. However, those skilled in the art will understand that the BG 105 may not be able to support selected LTE bands and / or selected CA combinations. For example, if LTE bands 8, 9 and 10 are not owned by the BG 105 are supported, the table 400 can have a different set of CA combinations 445 , 450 , 455 , 480 , 485 , 490 with any CA combination that includes any of LTE bands 8, 9 and 10 being removed. In another example, the BG 105 Be notified that a selected LTE band (e.g. LTE band 4) is not available for a number of reasons. Accordingly, the table 400 can be updated by choosing from the set of CA combinations 430 , 435 , 440 all CA combinations that contain LTE band 4 are removed, while the set of CA combinations 465-490 is completely removed because the selected PCC 460 which is LTE band 4.

The exemplary embodiments that use the prioritization of the first mechanism can be implemented for further conditions and scenarios. As described above, the first mechanism can generally be used to advertise an ability to use LTE bands for CA functionality. The advertising using the first mechanism of the embodiments can be further refined when certain network conditions or events have been detected. That is, the first mechanism of the embodiments can use a more selective way of advertising the UE RFBs.

In a first example, when the BG 105 detects bad network conditions (e.g. the BG is 105 closer to an edge of the network, compared to a threshold value, a relatively low received signal strength indicator (RSSI) is determined, etc.), then the BG 105 Restrict the advertising of CA combinations only to those UE RFBs that appear in the order 415 available. That is, the table 400 may be updated when the poor network conditions are detected to include the sets of CA combinations including non-UE RFBs such as the set of CA combinations 445 , 450 , 455 , 480 , 485 , 490 , to remove. In this way, the sets of CA combinations containing only UE RFBs can be used.

In a second example, if the BG 105 determines that a registration procedure repeatedly fails in a particular network, the BG 105 Advertising CA combinations only on those in the order 415 Restrict existing UE RFBs. For example, the registration procedure may fail due to a relatively large BG capability report (e.g., including all CA combinations in the BG capability report may increase the size of the BG capability report). Thus, in a substantially similar manner to the first example described above, the sets of CA combinations containing only UE RFBs can be used.

As noted above, the embodiments may provide a second mechanism related to taking measurements when requested by the network. For example, if the BG 105 indicates CA capability, the network can keep track of optimal LTE bands to use for CA functionality. To the quality of the LTE bands for the BG 105 can be determined by the BG 105 the transceiver 120 use to tune to the requested LTE band and take measurements. The measurements can then be transmitted to the network for consideration in the CA functionality.

Those skilled in the art will understand that there are two approaches to performing the measurements: gap measurements and gapless measurements (GM). In the case of a gap measurement, the BG 105 the transceiver 105 to tune away from a first LTE band, tune into a second LTE band requested by the network, perform the measurements on the second LTE band, and then tune back to the first LTE band. However, this creates a gap in the connection using the first LTE band during the time that the transceiver is 105 is tuned to the second LTE band in order to perform the measurements. While the likelihood can be minimized, there is still a risk of missing data transmitted over the first LTE band during this gap time.

In a GM, the transceiver can 120 of the BG 105 be a multi-transceiver. That is, the transceiver 120 may be able to tune to multiple LTE bands at the same time. Thus, the BG 105 a first section of the transceiver 105 use to tune to a first LTE band. The network may require measurements to be taken for a second LTE band. If available, a second section of the transceiver can be used 105 can be used to tune to the second LTE band while the first section continues to tune to the first LTE band. The second section can therefore be used to carry out the measurements. In this way there is no gap in the connection using the first LTE band and data that is transmitted during the time during which the measurements are carried out in the second LTE band can still be received via the first LTE band . However, those skilled in the art will understand that the use of GMs requires more power than the transceiver 105 is used in a more complex way. Furthermore, the GM may not be available even if the transceiver is 120 is a multi-transceiver. For example, the BG 105 Be CA capable and the CA functionality can be used so that the first section of the transceiver 120 is used for a first LTE band (e.g. PCC) and the second section of the transceiver 120 is used for a second LTE band (e.g. SCC). The network may request that a measurement be made for a third LTE band. In such a scenario, the BG is 105 in certain circumstances unable to run a GM as there may not be a free section of the transceiver 120 that can tune to the third LTE band without tuning away from the first LTE band or the second LTE band.

The GM can have another ability of the BG 105 which is advertised in the network. Under conventional operations, the BG transmits 105 on request, a data package which the capabilities of the BG 105 indicates. For example, the data packet can be limited to different sizes, such as from 800 to 1200 bytes, 1,000 to 1,500 bytes, or up to 2,500 bytes. If the BG 105 Is CA-capable, a substantial portion of the data packet can be occupied by the CA combination advertisement, which was described in detail above. Another skill that is included in the data package is the GM skills. Using the conventional operations, even if GMs cannot be performed, the data packet still includes GMs that are not supported. For example, it may contain a null value for a specific GM that is not supported.

Those skilled in the art will understand that there are a variety of different types of GMs. In a first example, the GM can be related to inter-frequency (IF) gapless measurements (IF GMs) for individual LTE bands. In a second example, the GMs can be related to inter-RAT (IR) gapless measurements (IR GMs) for individual LTE bands. In a third example, the GMs can be related to IF GMs for each CA combination. In a fourth example, the GMs can be related to IR GMs for each CA combination.

With these numerous types of GMs, it is evident that the data packet for the BG capability can also be substantially occupied by the GM capabilities. In a specific example, the data packet can be limited to 1,184 bytes. In this example, there can be 13 LTE bands that are supported. A total of 6 UTRA bands can also be supported, a total of 61x bands can be supported and a total of 4 GERAN bands can be supported. Accordingly, there can be a total of 16 non-LTE bands that are supported. There can also be 79 CA combinations approved by the BG 105 get supported. Thus, in this example, the IF-GMs for individual LTE bands 169 Occupy bits (13 × 13); the IR-GMs for individual LTE bands can occupy 208 bits (13 × 16); the IF-GMs for CA combinations can occupy 1,027 bits (79 × 13); and the IR-GMs for CA combinations can occupy 1,264 bits (79 × 16). Given the size of each GM and other information to be included, the GM section to be included in the data packet can be 333.5 bytes. This occupies about 28% of the data packet size.

As the data packet for the BG capability information increases in size, particularly since all GMs are included in the data packet, regardless of whether the GMs are actually performed or not, this large size can cause various problems. For example, a legacy eNB may not be able to process a data packet that is larger than 500 bytes, resulting in the data packet being dropped and also causing attach errors. In another example, the network may be the BG 105 not providing sufficient uplink grant to send the full packet of data, which leads to network timeouts and eventually causes attach errors to occur.

The embodiments provide a second mechanism in which a preliminary operation is performed prior to generating and transmitting the data packet, which is the capability of the BG 105 indicates. The preliminary operation can introduce an indicator of a particular type of GM that allows the execution of the GM to be truly optional. If the option is exercised not to execute the GMs for the specific species, then the corresponding GMs can be omitted from the data packet, which results in a reduction in the overall size of the data packet.

As described above, the processor can 110 of the BG 105 a GM application 127 that is configured to set indicators for various types of GMs that the BG is currently configured to perform. Again, examples of the types of GMs may include the IF-GMs for individual LTE bands, the IR-GMs for individual LTE bands, the IF-GMs for CA combinations, and the IR-GMs for CA combinations. The GM application 127 can be configured to determine whether the BG 105 unable to run any of these GMs. The GM application 127 can generate an indicator for each of these types of GMs, so the GM application 127 can set the indicator as being able or unable to carry out the relevant GMs. In a particular embodiment, the display can be a Boolean signal. Thus, the network can receive the indicators, and if any indicator indicates that the BG 105 is unable to perform a particular type of GM, then the network may be aware that a subsequent BG capability data packet may omit the section associated with the identified type of GM. So only for those GMs whose indicators indicate a positive ability are GMs from the BG 105 advertised to the network.

5 shows a procedure 500 for generating indicators that are associated with a gapless measurement, according to various exemplary embodiments. The procedure 500 may refer to the second mechanism of the embodiments in which the BG 105 Indicators for the different types of gapless measurements set by the BG 105 can be carried out, with the indicators indicating whether the complete measurement can be carried out. As discussed above, the use of the indicators may be a feature supported by the PCell and supported by the BG 105 is performed. Thus the procedure 500 from the BG 105 carried out and the procedure 500 will be related to the system 100 from 1 described.

In 505 determines the BG 105 a capability of the transceiver 120 . In particular, at 510, the BG determines 105 whether the transceiver 120 is a multi-transceiver. When the transceiver 120 is not a multi-transceiver, it can be assumed that a complete measurement cannot be carried out under any circumstances. Thus, in 515, the BG 105 set all indicators for the different types of GMs that cannot be performed (e.g. a value of o). The BG 105 can do the procedure 500 until 585 continue, in which the indicators are transmitted to the network. Since no types of GMs are performed, any subsequent data packets indicating BG capability can omit any data related to GM.

When the transceiver 120 is a multi-transceiver, GMs may be possible. For the purpose of describing the procedure 500 can be assumed to be the transceiver 120 has a primary transceiver used for the PCell and at least one secondary transceiver used for any SCell or GM. This is how in 520 determines the status of the secondary transceiver.

In 525 determines the BG 105 whether the secondary transceiver for IF-GMs is available for individual LTE bands. If the BG 105 detects that the secondary transceiver is not available, the indicator for IF-GMs for individual LTE bands in 530 to be set to incapable. If the BG 105 determines that the secondary transceiver is available, the indicator for IF-GMs for individual LTE bands in 535 can be set to enabled.

In 540 determines the BG 105 whether the secondary transceiver for IR-GMs is available for individual LTE bands. If the BG 105 detects that the secondary transceiver is not available, the indicator for IR-GMs for individual LTE bands in 545 to be set to incapable. If the BG 105 determines that the secondary transceiver is available, the indicator for IR-GMs for individual LTE bands in 550 can be set to enabled.

In 555 determines the BG 105 whether the secondary transceiver for IF-GMs is available for CA combinations. If the BG 105 determines that the secondary transceiver is not available, the indicator for IF-GMs for CA combinations in 560 can be set to disabled. If the BG 105 determines that the secondary transceiver is available, the indicator for IF-GMs for CA combinations in 565 can be set to enabled.

In 570 determines the BG 105 whether the secondary transceiver for IR-GMs is available for CA combinations. If the BG 105 detects that the secondary transceiver is not available, the indicator for IR-GMs for CA combinations in 575 to be set to incapable. If the BG 105 determines that the secondary transceiver is available, the indicator for IR-GMs for CA combinations in 580 can be set to enabled.

Subsequently transmitted on the basis of the various indicators for the IF-GMs for individual LTE bands, for the IR-GMs for individual LTE bands, for the IF-GMs for CA combinations and for the IR-GMs for CA combinations were determined, in 585 the BG 105 the indicators the network. Thus, the BG 105 indicated to the network an ability to only perform the GMs for the identified species, whose indicator is capable of inclusion in the subsequent data packets for the ability of the BG 105 is marked.

The exemplary embodiments provide an apparatus, a system and a method for advertising network capability of a BG. In a first mechanism, for a BG that is CA-capable, the CA combinations can be advertised, so that the BG can select the CA combinations with the highest relevance for the BG to advertise, while CA combinations of lower relevance only be advertised when limited space is available for advertising. In a second mechanism, it is determined that a BG transceiver is able or unable to execute GMs of various types, so that indicators of capability are initially transmitted to the network to indicate whether a data packet has the BG capability Intended to include GMs of various types.

It should be noted that the above exemplary embodiments were generally described with reference to the operation of an LTE network. It should be noted, however, that the exemplary embodiments can also be used in relation to any networks that CA or GMs advertise or implement, including networks that are not yet operational, such as 5G networks.

Those skilled in the art will recognize that the exemplary embodiments described above can be implemented in any suitable software or hardware configuration, or combinations thereof. An exemplary hardware platform for carrying out the exemplary embodiments can include, for example, an Intel x86-based platform with a compatible operating system, a Mac platform and a MAC OS, a mobile device with an operating system such as iOS, Android, etc. In another example, the exemplary embodiments of the method described above can be executed as a program that includes lines of code that are stored on a non-transitory computer readable storage medium and that, when compiled, can be executed on a processor or microprocessor.

It will be apparent to those skilled in the art that various modifications can be made in the present invention without departing from the spirit and scope of the invention. It is therefore intended that the present invention cover modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (13)

Method comprising: on a user device (105): Determining (315) a number of available slots for advertising carrier aggregation (CA) combinations to a network; Determining (335) an order of priority for a plurality of bands that are part of the CA combinations; Determining (340) a list of the CA combinations based on the order of priority; and Transmitting (345) a portion of the list of CA combinations to the network in priority order, the portion corresponding to the number of seats available; wherein determining (335) the order of priority comprises: Determining a timing parameter for each of the bands based on how recently the user device occupied each of the bands, with priority given to the bands that were most recently used. Procedure according to Claim 1 wherein determining (335) the priority order further comprises: determining a neighboring band for each of the bands that have been determined to have priority based on a timing parameter. Procedure according to Claim 2 wherein the CA combinations include any of all bands available to the user equipment (105) or only include bands determined to have priority based on the timing parameter and neighboring bands. Procedure according to Claim 1 wherein the determining (335) of the priority order is based on a number of component carriers used for the CA combinations. Procedure according to Claim 1 , where the plurality of tapes are Long Term Evolution (LTE) tapes. Procedure according to Claim 1 where the portion of the list is the entire list if a number of CA combinations is less than the number of available slots. Procedure according to Claim 1 , further comprising: receiving a second list of CA combinations from the network; and adding the CA combinations in the second list to the list of CA combinations, the CA combinations on the second list having a highest priority. Procedure according to Claim 1 , wherein the list is location-dependent and the user device (105) determines a further list of CA combinations on the basis of the fact that the user device (105) is at a different location than the location at which the list of CA combinations is determined was located. A user device (105) comprising: a transceiver (120) configured to connect the user device (105) to a network, the user device (105) and the network configured for carrier aggregation (CA) functionality; and a processor (110) determining a number of available locations to advertise CA combinations to the network, the processor (110) determining an order of priority for a plurality of Long Term Evolution (LTE) bands that are part of the CA combinations are, the processor (110) determining a list of the CA combinations based on the order of priority, the transceiver (120) transmitting a portion of the list of CA combinations to the network in the order of priority, the portion of the number corresponds to the available positions, wherein the processor (110) determines the order of priority by determining a timing parameter for each of the LTE bands based on how recently the user equipment has occupied each of the LTE bands, with priority being given to the LTE bands that were most recently occupied is given. User device (105) Claim 9 wherein the processor (110) further determines the order of priority by determining a neighboring band for each of the bands determined to have priority based on a timing parameter. User device (105) Claim 10 wherein the CA combinations include one of all LTE bands available to the user equipment (105) or only include LTE bands that have been determined to have a priority based on the timing parameter and the neighboring bands . User device (105) Claim 10 wherein if the processor (110) determines that the user device (105) is near an edge of the network, having a received signal strength indicator (RSSI) that is lower than a threshold or that a registration procedure on a particular network repeats a number of If a time that is greater than a threshold value has failed, the processor (110) only records tapes that have been determined to have priority on the basis of the timing parameter and the neighboring tapes in the list of CA combinations. User device (105) Claim 9 wherein the processor (110) determines the order of priority based on a number of component carriers used for the CA combinations.

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