Field of the invention

The present invention relates to a method as defined in the preamble of claim 1, i.e. a method for transmission of

Sounding Reference Signals (SRSs) on an uplink carrier of a telecommunication system, in which system:

- a set of SRSs is predefined, each predefined SRS being

configured as having a bandwidth and a frequency domain

position; and

- a predefined SRS region includes a set of all Resource

Blocks (RBs) being usable for transmission of said predefined

SRSs on said uplink carrier, said set of RBs being smaller than a total set of RBs being available on said uplink carrier.

The present invention also relates to a method as defined in the preamble of claim 25, i.e. a method of an eNodeB for

configuration and reception of a transmission of SRSs on an uplink carrier of a telecommunication system, in which system:

- a set of SRSs is predefined, each predefined SRS being

configured as having a bandwidth and a frequency domain

position; and

- a predefined SRS region includes a set of all RBs being usable for transmission of said predefined SRSs on said uplink carrier, said set of RBs being smaller than a total set of RBs being available on said uplink carrier. The present invention also relates to a User Equipment (UE) as defined in the preamble of claim 28, i.e. a UE being arranged for performing transmission of SRSs on an uplink carrier of a telecommunication system, in which system:

- a set of SRSs is predefined, each predefined SRS being

configured as having a bandwidth and a frequency domain

position; and - a predefined SRS region includes a set of all RBs being usable for transmission of said predefined SRSs on said uplink carrier, said set of RBs being smaller than a total set of RBs being available on said uplink carrier. The present invention also relates to an eNodeB, as defined in the preamble of claim 29, i.e. an eNodeB arranged for

configuration and reception of a transmission of SRSs on an uplink carrier of a telecommunication system, in which system:

- a set of SRSs is predefined, each predefined SRS being configured as having a bandwidth and a frequency domain position; and

- a predefined SRS region includes a set of all RBs being usable for transmission of said predefined SRSs on said uplink carrier, said set of RBs being smaller than a total set of RBs being available on said uplink carrier.

The present invention also relates to a computer program and a computer program product implementing the above methods.

Related art and background of the invention

In prior art telecommunication systems, such as LTE Rel-10 (LTE-Advanced) , a terminal (UE) can utilize carrier

aggregation. For carrier aggregation, data can be

simultaneously received on multiple downlink carriers and data can be simultaneously transmitted on several uplink carriers. According to the LTE Rel-10 standardization documentation, the notion of cell is used to denote a combination of downlink resources, and optionally also a combination of uplink

resources, where the linking between the carrier frequency of the downlink resources and the carrier frequency of the uplink resources is indicated in the system information transmitted on the downlink resources. Hence, the meaning of a cell may not be the same as a geographical area as usually is the case for cellular communication systems.

In this document, the invention will be described in relation to, and using the notation of the LTE Rel-10 standard. However, the invention may, as is clear for a skilled person also be implemented in essentially any telecommunication standard having corresponding capabilities as the LTE Rel-10 standard prescribes .

Typically, the UE is mostly confined to transmit and receive on a single cell. This cell is referred to as the Primary Cell (PCell) . In the downlink, the carrier corresponding to the

PCell is the Downlink Primary Component Carrier (DL PCC) , while in the uplink, the carrier corresponding to the PCell is the Uplink Primary Component Carrier (UL PCC) .

Depending on UE capabilities, Secondary Cells (SCells) can be configured to form, together with the PCell, a set of serving cells. In the downlink, the carrier corresponding to a SCell is a Downlink Secondary Component Carrier (DL SCC) while in the uplink it is an Uplink Secondary Component Carrier (UL

SCC) . The UE can then aggregate transmissions over multiple serving cells.

The Physical Downlink Control Channel (PDCCH) that includes the DL assignments for the SCell, or UL grants for the SCell, can be transmitted either on the DL SCC or on the DL PCC. The latter case is referred to as cross-carrier scheduling.

Figure 1 schematically illustrates the aggregation of two cells, where cross-carrier scheduling is made by a PDCCH

located on the PCell. The linkage between an uplink- and downlink carrier in a cell is in Frequency Division Duplex (FDD) systems given by a fixed duplex distance. A UE that is configured with carrier aggregation may only transmit the Physical Uplink Control Channel (PUCCH) on its PCell, i.e. the UL PCC.

According to the LTE Rel-10 standard, the configuration of a PCell is UE-specific, i.e., a component carrier can be either part of a PCell or of an SCell, depending on how it is configured for the given UE . In LTE Rel-10, all cells are backwards compatible and can be accessed by UEs of all previous system releases, even for UEs that do not support carrier aggregation. Thus, even if the SCell is cross-carrier scheduled for a given UE, since the SCell is backwards compatible, the DL SCC includes a control region comprising at least 1 OFDM symbol, and spanning the whole carrier bandwidth. When the carrier bandwidth is 1.6 MHz, the control region comprises at least 2 OFDM symbols.

The PUCCH is transmitted on the outer Resource Blocks (RBs) on the UL PCC, and the number of RBs for the PUCCH may vary depending on system load. The PUCCH comprises HARQ feedback and Channel State Information (CSI) reporting. An RB is in LTE Rel-10 defined as a time-frequency resource comprising 0.5 ms and 180 kHz. In prior art disclosures, it has been shown that the number of RBs used for the PUCCH can be significant, depending on the periods configured for Channel Quality

Indicator / Precoding Matrix Indicator / Rank Indicator

(CQI/PMI/RI) reporting and Scheduling Request. RBs that are not used for the PUCCH could be used for data transmission on the Physical Uplink Shared Channel (PUSCH) . In prior art, it has been proposed to introduce non-backwards compatible SCells, i.e. cells which cannot be accessed by UEs of previous system releases. One such example is a DL SCC which does not include any control region, i.e. does not include any PDCCH. It would therefore always have to be scheduled by cross-carrier scheduling from the PCell. One consequence is then that, due to the absence of a control region, this non-backwards compatible carrier cannot be configured as a PCell for any UE, since the standard does not allow cross-carrier scheduling to a PCell from a SCell. Hence, the associated UL SCC would never comprise a PUCCH, since only the PCell may contain a PUCCH. It has therefore been envisaged that a non-backwards

compatible carrier, not containing any PUCCH, will be needed if a non-backwards compatible DL SCC is introduced. Removal of the PUCCH could thereto be assumed to improve the efficiency since there is less control overhead and more RBs would be available for the PUSCH as a result from the removal.

In order to be able to schedule the PUSCH, the base station (eNodeB) receives a Sounding Reference Signal (SRS)

transmitted from the UE . The SRS are used by the eNodeB, e.g. to estimate the uplink channel quality. The uplink channel quality is further used for determining the RB allocation and for determining the applied modulation and coding scheme of the PUSCH transmission.

However, in the LTE Rel-10 system, the SRS transmission scheme is designed based on the presence of a PUCCH. Since the PUCCH is removed for the non-backwards compatible UL SCC, proper and efficient scheduling decisions are difficult to make, since the SRS transmission has been optimized for a backwards

compatible UL SCC having a different configuration. Due to these difficulties, a non-optimal scheduling results, which does not make use of all available resources in the system. Aim and most important features of the invention

It is an object of the present invention to provide a

transmission of SRSs that solves the above stated problem.

The present invention aims to provide a more efficient

resource scheduling than the inferior scheduling known in the background art.

The object is achieved by the above mentioned method according to the characterizing portion of claim 1, i.e. by the steps of:

- creating at least one shifted SRS by shifting said

predefined frequency domain position for at least one of said predefined SRSs, thereby creating an extended SRS region

including at least one additional RB being separate from said predefined SRS region; and

- transmitting said at least one shifted SRS on said uplink carrier.

The object is also achieved by the above mentioned method according to the characterizing portion of claim 25, i.e. by the steps of:

- providing configuration instructions to an UE in said system, said instructions relating to at least one shifted SRS to be created by shifting said predefined frequency domain position for at least one of said predefined SRSs, thereby creating an extended SRS region including at least one additional RB being separate from said predefined SRS region; and - receiving on said uplink carrier at least one shifted SRS.

The object is also achieved by the above mentioned UE

according to the characterizing portion of claim 28, i.e. by - a shift creating entity, being arranged for creating at least one shifted SRS by shifting said predefined frequency domain position for at least one of said predefined SRSs, thereby creating an extended SRS region including at least one additional RB being separate from said predefined SRS region; and

- a transmission entity, being arranged for transmitting said at least one shifted SRS on said uplink carrier.

The object is also achieved by the above mentioned eNodeB according to the characterizing portion of claim 29, i.e. by - a configuration entity, arranged for providing configuration instructions to an UE in said system, said instructions relating to creation of at least one shifted SRS by shifting said predefined frequency domain position for at least one of said predefined SRSs, thereby creating an extended SRS region including at least one additional RB being separate from said predefined SRS region; and

- a reception entity, arranged for receiving said at least one shifted SRS on said uplink carrier.

The object is also achieved by the above mentioned computer and computer program implementing the methods.

The methods, UEs and eNodeBs of the according to the present invention are characterized in that configuration,

transmission and reception of SRSs are performed in such a way that an extended SRS region is created by performing shifts on the frequency domain position of one or more predefined SRS. Hereby, SRSs can be transmitted on an increased number of RBs, whereby more RBs on the UL carrier can be sounded and thus utilized for proper scheduling.

Thus, since the SRS bandwidth in LTE is less than the

bandwidth of the carrier, and the carrier must not comprise a PUCCH, a number of RBs are freed up to be possible to schedule By utilization of the invention, these freed up RBs can be included in the extended SRS region, and can thus be sounded. This increases the bandwidth of the UL carrier that is usable for PUSCH transmissions. Removal of the PUCCH will therefore by the use of the invention, improve the spectral efficiency of the system.

Detailed exemplary embodiments and advantages of the SRS configuration, transmission and reception according to the invention will now be described with reference to the appended drawings illustrating some preferred embodiments.

Brief description of the drawings

Fig. 1 shows carrier aggregation by cross scheduling.

Fig. 2 shows one embodiment of the invention.

Fig. 3 shows one embodiment of the invention.

Fig. 4 shows a telecommunication system according to the invention .

Detailed description of preferred embodiments

In LTE Rel-10, physical resource blocks (RBs) in an uplink carrier are enumerated as n _PRB = 0,1, ... , Ν^ _β — 1. Each RB contains Ns^ ^B = 12 resource elements (REs) and the relation between the RB and resource element fc is · The resource elements are enumerated from k = 0,1, ... , N _RB N^ _C — 1 and each resource element is in turn mapped to a subcarrier.

Only 6 bandwidths are predefined in LTE, corresponding to

N _RB = 6, 15, 25, 50, 75 and 100 RBs .

The number of RBs that can be scheduled on the PUSCH for any UE is further constrained to fulfill M _RB ^SCH = 2 ^tt2 · 3 ^tt3 · 5 ^tts <

where ^.^.^is a set of non-negative integers.

The bandwidth of the predefined SRS is configured to comprise ^m SRS,b RBs. The bandwidth of the SRS is constrained to ni _SRSb = 2(i+a ₂ ) .3«3.5«5 < _w h _ere a ₂ , a ₃ , a ₅ is a set of non-negative

integers. Table 1 is one example of possible predefined SRS bandwidths in LTE Rel-10. The predefined SRS bandwidth

configuration C _SRS in table 1 is a cell-specific parameter configured by higher layers and the SRS bandwidth

configuration 5 _SRS in table 1 is a UE-specific parameter

configured by higher layers.

Table 1 shows an example of an SRS configuration for the

uplink bandwidth of 80<Λ¾<110, for m _SRSf) and N _b , where b = 0,1,2,3 . Different SRS bandwidths can be configured, e.g. a wideband

SRS (J^SRS.O) ^{or one} °f several narrowband SRSs (J^sRS.i ' ^m SRS,2 > ^m SRS,3 ) · The narrowband SRSs will be transmitted with higher power per RE and are beneficial when the UE is power-limited. To cover the whole system bandwidth, frequency hopping (FH) can be used for the narrowband SRSs, thereby covering the same RBs as the wideband SRS. Depending on the system bandwidth and expected number of RBs for PUCCH, a suitable SRS bandwidth

configuration should be selected. SRS-Ba ndwidth SRS-Ba ndwidth SRS-Ba ndwidth SRS-Ba ndwidth

SRS bandwidth

configuration = 0 3=1 = 2 ^SR ,=3

QRS '"SRS.O N ₀ ^OT SRSJ ^SRS^ ^W %RS N ₃

0 96 1 48 2 24 2 4 6

1 96 1 32 3 16 2 4 4

2 80 1 40 2 20 2 4 5

3 72 1 24 3 12 2 4 3

4 64 1 32 2 16 2 4 4

5 60 1 20 3 4 5 4 1

6 48 1 24 2 12 2 4 3

7 48 1 16 3 8 2 4 2

Table 1

LTE-Advanced supports spatial multiplexing on the uplink, for which transmission is performed on up to 4 antenna ports. One SRS is transmitted per antenna port. The resource elements (REs) on antenna port p predefined to be used for SRS are modulated by an SRS sequence according to:

a?> = Ke^^f^k), k = 0,1 ^s^- 1 , (Eq.

2k+k ₀

where K is a constant, it and v are integers, n _cs G {0,1, ...,7} is a configurable cyclic shift, and f _UiV {k) is a complex valued sequence with constant magnitude. A (discrete) time-domain signal is obtained by a (discrete) Fourier transform of the sequences .

The predefined frequency domain position for the SRS, which can be seen as a starting position for the SRS, i.e., the resource element index corresponding to the first RE of the SRS in the frequency domain, is obtained when k = 0 and is defined by:

p ⁾ +∑ ^R SRS _,b N n _b , (Eg. 2) where for normal uplink subframes, fc„ is defined by: = ({N /2l-m _S K _>0 /2)N∞ + k? ₍ !. (Eq. 3) The parameter k _C G {0,1} is UE-specific and is implicitly configured by higher layers. The starting position defined in Eq. 2 can be obtained from a tree based design in order to simplify orthogonal multiplexing of SRS of different bandwidths from different UEs. The tree property can be realized in table 1, where rn _SRSi = N _i+1 m _SRSi+1 . This means that for a given configuration C _SRS , the frequency domain positions, i.e., the location of the RBs, for the SRS of different UEs, either completely overlap, or do not overlap at all. Partial overlapping can be avoided in LTE Rel-10, which in turn guarantees that SRS can remain orthogonal among UEs .

If frequency hopping of the SRS is not configured, the

frequency domain position, i.e. the RE index, remains constant and is obtained by using:

4n _RRC

n _b modN _f c, (Eq. 4) mSRS,b where n _RRC G {0,1, ... ,23} is a UE-specific parameter configured by higher layers .

If frequency hopping is enabled, the parameter Z¾ _op G {0,1,2,3} is configured and

' ^■ 'hop

{(F _b frs _R s) + [4n _RRC /m _SRS|Z ,J)mod N _b , otherwise. Here, F _b (n _SRS ) is a time-dependent hopping sequence. The LTE-Advanced system thus comprises a set of predefined SRSs which can have configurable bandwidths and frequency domain positions through a set of parameters C _SRS , B _SRS , b _hop , kf _c and n _RRC . In addition, SRS properties pertaining to the time-domain are also configurable.

Orthogonality among SRSs transmitted in a same RB can in LTE Rel-10 be obtained by transmission on mutually disjoint sets of subcarriers . This is possible since the SRS sequence only modulates every second subcarrier (Eq. 1) and this can be controlled by the parameter kf _c . Hence, orthogonal multiplexing can be achieved even if UEs are configured with different SRS bandwidths n _SRSb , by using different values of kj^. When the SRS bandwidths ni _SRSb are the same (and they use the

(p)

same value of k _jC ) ) , orthogonal SRSs can also be obtained using different cyclic shifts n _cs for a given sequence . For a positive integer q, when the sequence length is q · 8, the cross-correlation in the frequency domain between two

sequences of same length using different cyclic shifts is:

Since the SRS sequence occupies 6 REs per RB, q = 3 yields the smallest sequence length, corresponding to 4 RBs, over which SRS sequences can become orthogonal.

The condition of orthogonality can also be understood from considering the time-domain, by that the sequence length should be a multiple of 8 in order to accommodate 8 non- overlapping cyclically shifted signals. All SRS bandwidth are multiples of 4 RBs in LTE, as can be seen in table 1. This implies that there can be no SRS bandwidth equal to =

6, 15, 25, 50 and75 RBs.

Orthogonality among SRSs for different antenna ports can be obtained by cyclic shifts only, or by cyclic shifts and different transmission combs. non-limiting example, if we consider Eq. 3, when k (P)

TC 0 and N _RB = 100 , the lowest starting RB, i.e. the lowest frequency domain position, for the SRS becomes n min =2, by assuming that _SRS0 = 96 in table 1. Hence, the RBs n _PRB = 0,1,98,99 cannot be used for SRS transmission in this example. Since C _SRS is a cell-specific configuration, these RBs can also not be used for SRS transmission by any UE in the cell. In LTE Rel-10, this would not be an issue since those RBs close to the edge of a total set of RBs being available on said uplink carrier would typically be used for the PUCCH and thus not need to be sounded by transmission of SRSs.

Thus, in the LTE Rel-10 system, the SRS transmission scheme is designed based on the presence of a PUCCH and the SRSs do not need to be transmitted on RBs usable for the PUCCH. However, if there is no PUCCH, these RBs could potentially be used by the PUSCH and not being able to sound the RBs becomes a problem. But, it may not be possible to transmit the SRS on the extra RBs coming from the removed PUCCH, which would make it difficult to make proper scheduling decisions on those RBs. It is a problem if the extra RBs cannot be used, since that would diminish the aforementioned efficiency improvements. This can also be seen in table 2, which includes the lowest starting RB, n = min and the largest starting RB,

n max (P) / _M RB , for each SRS configuration in table 1. In other words, table 2 shows how the different predefined SRS bandwidths can be positioned. From Table 2, it can be seen that the number of RBs that cannot be sounded ranges from 4 (C _SRS = 0) to 52 (C _SRS = 7), when N _R g = 100, which clearly indicates poor utilization of available transmission resources due to inferior scheduling possibilities.

Table 2

In table 2, it can be observed that n ^~ + m _SRS0 + n ^~ = 100 when

^SRS ⁼ 0- Hence, the SRS is located on RBs symmetrically in the carrier. By inspection of Eq. 3, it is realized that when N^ _Q is an odd number, n ^~ = (N _R B — l)/2— m _SRS0 /2 and the number of RBs being located on RBs higher than for the SRS is — m _SRS0 — n ^~ = n ^~ + 1, which is 1 more RB than being located on RBs lower than for the SRS.

However, as described above, in the LTE Rel-10 system, the SRS transmission scheme is designed based on the presence of a PUCCH. In LTE Rel-10, the SRS bandwidth is less than the bandwidth of the carrier. This becomes an issue if the carrier does not comprise a PUCCH since not all RBs that would be usable for PUSCH transmissions can then be sounded.

Hence, in LTE Rel-10, it may not be possible to transmit the SRSs on the extra RBs resulting from the removed PUCCH, i.e. the freed up RBs previously having been used for transmission of the PUCCH, which would make it difficult to make proper scheduling decisions on those RBs. Thereby, the aforementioned efficiency improvements are diminished, since the extra RBs cannot be properly used. The present invention discloses a method, a UE, and an eNodeB related to and arranged for SRS transmission in a

telecommunication system on an UL carrier that does not

contain a PUCCH, which will solve the above stated problems. According to an aspect of the invention a set of SRSs is

predefined, each predefined SRS being configured as having a bandwidth and a frequency domain position. One example of such predefined set of SRSs was described above in table 1. Thus, the predefined set of SRSs typically is the set defined in the Evolved Universal Terrestrial Radio Access (E-UTRA) LTE Rel-10. This predefined set of SRSs covers a predefined SRS region, where the SRS region includes a set of all RBs that could be used when these SRSs are transmitted on the uplink carrier.

As was described above, the SRS bandwidth is less than the bandwidth of the UL carrier, i.e. the set of RBs of the SRS region is here smaller than a total set of RBs being available on the UL carrier.

According to the invention, at least one shifted SRS is

created. The shifted SRS is created by shifting the predefined frequency domain position for at least one of the predefined

SRSs such that it utilizes an RB not being covered by that SRS (or any other of the existing predefined SRSs) before the shift has been made. Thus, at least one SRS typically being defined in LTE Rel-10 is shifted, whereby (a non-empty set of REs in) an additional RB is utilized for transmitting the shifted SRS .

By this shifting operation, an extended SRS region is created, which includes this at least one additional RB . Thus, the extended SRS region includes at least one additional RB being separate from, i.e. not being included in, the predefined SRS region. In other words, the SRS region being predefined for

LTE Rel-10 is by the shift of at least one SRS extended by at least one additional RB not being covered in the SRS region, thereby creating the extended SRS region.

The extended SRS region is then utilized for transmission of the least one shifted SRS on the UL carrier. As a result, at least one additional RB will be sounded by the transmission, which means that at least one additional RB will be useable for high quality data transmission. Thus, by creation of this extended SRS region, more RBs become usable for PUSCH

transmissions, since the freed RBs previously being used for transmission of the PUCCH, can now be sounded and can thus be properly utilized for data transmission. The transmission of the at least one shifted SRS can here be performed in normal uplink subframes. An advantage of the shifting operation is that SRSs could be transmitted over all RBs in the carrier, even if the total number of RBs in the carrier is not a multiple of 4, i.e., the SRS bandwidth multiple.

A further advantage of the invention is that it reuses the SRS sequences from prior art LTE-Advanced system, thereby keeping the complexity down both at the transmitter and receiver. According to an embodiment of the invention, one or more predetermined SRS having a maximal bandwidth are shifted in order to create the extended SRS region. Here, a number of RBs ^M SRS _, o ⁼ RB — Δ being used for transmission of such a predefined maximal bandwidth SRS is a number Δ of less RBs than a number of RBs included in the total set of RBs being available on the UL carrier, where the number Δ is an positive integer larger than zero, Δ> 0. Thus, the total UL bandwidth is NRB , and the SRS bandwidth is m _SRS0 = N^ _Q — Δ, which is Δ RBs less than the UL bandwidth .

According to the embodiment, a definition is made of up to a number Δ + l of different frequency domain positions TISTART ⁼ 0,1, ... , Δ for at least one shifted SRS. These Δ + l different frequency domain positions are defined such that they include all feasible frequency domain positions on the UL carrier.

The different defined frequency domain positions could, e.g., be enumerated as n _START = 0, 1, ... , Δ . One or more of the number Δ + 1 of different frequency domain positions n _START = 0,1, ... , Δ are then utilized for transmission of the at least one shifted SRS. By this embodiment, SRS transmission, which also makes

sounding possible, is achieved for a telecommunication system, in which the number of RBs available for data transmission is larger than the maximum SRS bandwidth. In particular it applies to an UL carrier that does not contain a control channel (PUCCH) .

According to an embodiment of the invention, the inclusion of all feasible frequency domain positions results in an extended SRS region including every one of the number Δ of RBs being unused for transmission of the predefined SRS having said maximal bandwidth. Thus, the entire UL carrier bandwidth can be utilized for transmission of the SRSs.

This is illustrated by figure 2, in which a non-limiting

example of this embodiment, where m _SRS0 = 4, N _R B = 6, Δ = 2 , is shown. In figure 2, the frequency domain position n _START = 1 illustrates the predefined frequency domain position of the maximal

bandwidth SRS, i.e. the only frequency domain position being defined in LTE Rel-10. It is clearly shown in figure 2 that the edge RBs, i.e. n _PRB = 0 and n _PRB = 5, are not included in the SRS region, and would thus not be sounded when the predefined set of SRSs would be transmitted.

By use of this embodiment of the invention, the maximal

bandwidth SRS is shifted such that the extended SRS region, i.e. the one or more shifted SRSs also covers the edge RBs

PRB ⁼ 0 ^an d TipRB = 5, as is illustrated by the frequency

bandwidth positions _START = 0 and _START = 2. Thus, by allowing multiple frequency domain positions

according to the invention, i.e. by utilizing shifted SRSs, it is possible to transmit SRSs, and thus to sound, the entire UL carrier bandwidth. In this document, the notion of frequency domain position has been illustrated by using a granularity of RB . It is

understood that the invention also includes other suitable definitions of the frequency domain position, e.g. where the frequency domain position refers to a resource element (RE) , i.e., a subcarrier. For example, two SRS may then have the same frequency domain position RBs while having different frequency domain position REs within those RBs, e.g., by using different transmission combs (kf^ ·

A consequence of using shifted SRSs, i.e. of using different frequency domain positions for the SRSs, is that SRSs may sometimes be partially overlapping. This would be the case in figure 2, if one UE is assuming n _START = 0 and another UE is assuming n _START = 2. An overlap could depend on the bandwidths of the shifted SRSs and, in case of frequency hopping, also the subframe number. If partial overlapping occurs, it implies that orthogonality may not be maintained even if the shifted SRSs have the same bandwidth. This problem does not preclude using shifted SRSs having different frequency domain positions, but the consequence of the loss of orthogonality may be a slight worse performance.

This orthogonality problem can, according to an embodiment of the invention, be solved by using two mutually disjoint sets of REs are usable for at least one frequency domain position of the at least one shifted SRS . This is possible since each

RB includes a predefined number of REs. In LTE Rel-10, each RB includes 12 REs. Hereby, the orthogonality can be restored for the shifted SRSs of the extended SRS region, even if the

shifts result in SRSs having partial overlaps. The two mutually disjoint sets can be achieved by utilizing odd and even REs, respectively, for the two shifted SRSs. Thus, different transmission combs, i.e. odd and even REs,

respectively, can be used within the extended SRS region in order to create mutually disjoint, and thereby orthogonal, sets.

The two mutually disjoint sets can also be achieved by

utilizing Time Division Multiplexing (TDM), i.e. by transmission of the shifted SRSs with partially overlapping frequency resources in different subframes, whereby

orthognality for the shifted SRSs is achieved. This,

embodiment utilizes that different subframe offsets can be configured for different UEs in the LTE Rel-10 system.

According to an embodiment of the invention, two different frequency domain positions are usable for the at least one shifted SRS, where the two different frequency domain

positions result in two different mutually disjoint sets of REs. This is possible since each RB includes a predefined number of REs, as stated above.

Thus, two different frequency domain positions are facilitated, e.g., n _START = 0 and Δ, which are associated with two different disjoint RE sets, which restores orthogonality for the shifted SRSs .

The invention also includes a method for creating the extended SRS region when at least one SRS having a smaller bandwidth, i.e. at least one of m _SRS1 ,m _SRS2 ,m _SRS3 (i.e. non-wideband SRSs), is shifted. According to this embodiment, the extended SRS region is then created by at least one shifted SRS having a bandwidth being smaller than a maximal bandwidth predefined for SRS in the system. Thus, at least one of the predefined SRSs J^SRS.I' ^SRS^' ^SRS.S having a smaller bandwidth is shifted by altering its predefined frequency domain position.

Thus, the frequency domain positions are here only changed for predefined non-wideband SRS bandwidths, i.e. m _SRS1 ,m _{SRS 2} ,m _{SRS 3} . The frequency domain positions are shifted for the shifted

SRSs such that one or more RBs not being within the sounding bandwidths of either the shifted non-wideband SRSs is within the sounding bandwidth of the maximal bandwidth SRS n _SRSOr and vice versa. Thereby, the extended SRS region includes at least one additional RB not being included in the predefined SRS region.

According to an embodiment, the extended SRS region here

typically includes one non-shifted predefined maximal

bandwidth SRS and at least one shifted non-maximal bandwidth SRS .

According to an embodiment of the invention, the extended SRS region covers, after at least one shifted SRS has been created, at least one RB being aligned with an edge RB of the total set of RBs being available on the UL carrier. According to an embodiment of the invention, the extended SRS region covers, after at least two shifted SRSs have been

created, two shifted SRSs being aligned with a first and a last RB, respectively, of the total set of RBs being available on the UL carrier. Thus, by use of these embodiments, the one or more of the edge RBs can be sounded, i.e. can be included in the extended SRS region, by shifting of SRSs having non-maximal bandwidths while remaining RBs can be sounded by the predefined maximal bandwidth SRS _SRS0 . These embodiments also assures orthogonality, since the shifted versions of non- maximal SRS bandwidths J^SRS.I' ^SRS^' ^SRS.S never will partially overlap .

This embodiment is shown in a non-limiting example in figure 3 for m _SRS0 = 96, m _SRS1 = 48 and m _SRS2 = 24 , where ^^ = 100 . The

wideband SRS (J^SRS.O ⁼ 96) is transmitted on RBs 2-97. For the shifted versions of the narrow-band SRSs (J^SRS.I ⁼ 48 and ^m SRS,2 ⁼ 24) , the frequency domain positions after shifting are made such that RBs 48-51 are never used. From figure 3, it is clear that the extended SRS region includes RBs 0, 1, 98 and 99, that were not included in the SRS region, and would

therefore never had been sounded without the use of the

concept of shifted SRSs according to the invention.

The method is not limited to excluding RBs from the center of the carrier from being used by narrow-band SRSs. The only requirement is that the excluded RBs will be in the sounding bandwidth of the wide-band SRS, such that a continuous

extended SRS region can result.

An advantage of this embodiment, i.e. shifting of non-wideband SRSs, is also that no signaling is be needed for indicating the frequency domain positions of the shifted narrow-band SRSs. For example, since the carrier bandwidth is known, the

frequency domain positions of the narrow-band SRS can be

aligned with the first and last RB of the carrier, as

illustrated in figure 3.

If the use of shifted narrow-band SRS is combined with

frequency hopping, the excluded RBs may also not be used. In figure 3, that implies that the set of RBs used for

transmitting frequency hopping SRS are RBs 0-47 and 52-99, i.e., in total 96 RBs. This also assures the shifted SRSs are not partially overlapping within the cell. The frequency domain positions of the shifted narrow-band SRSs are according to an embodiment arranged such that N _t shifted SRSs of bandwidth m _SRSi do not overlap in frequency. For example, the N _! = 2 frequency domain positions make sure the shifted SRS of bandwidth m _SRS1 do not overlap, as illustrated in figure 3. Also, the N ₂ = 4 frequency domain positions make sure that the shifted SRS of bandwidth Jn _SRS|2 do not overlap, etc. This

condition is trivially fulfilled for the SRS of bandwidth m _SRS0 since N ₀ = 1 and there can be no overlap. According to an embodiment of the invention, the extended SRS region, i.e. the at least one shifted SRS includes at least one narrow-band SRS as well as a maximal bandwidth SRS. Here, the creation of at least one shifted SRS is performed by

shifting the predefined frequency domain position for at least one of the predefined narrow-band SRSs and for the maximal bandwidth SRS, respectively.

Information regarding the shifting of the predefined SRSs, i.e. the creation of the extended SRS region by altering the

frequency domain positions for the predefined SRSs according to the above described methods, need to be conveyed to the UE, so that the UE knows how to create the extended SRS region, i.e. how to perform these shifts.

According to an embodiment of the invention, information

related to at least one frequency domain position being used for creating at least one shifted SRS is implicitly provided to the UE . This has an advantage in that no extra signaling is needed to convey this information

A predefined rule can, according to an embodiment, be utilized for providing such information implicitly. For example, the frequency domain position can be implicitly derived by the UE from an enumeration of a subframe, say t, in which the shifted SRS is transmitted, or any other pre-defined subframe or

subframe pattern, e.g., as n _START = t mod Δ . Related pre-defined rules for associating the transmission comb could, e.g., be a function of the frequency domain position n _START . A predefined pattern of frequency domain positions can, according to an embodiment, be utilized for providing such information implicitly. For example, the shifts on the

frequency domain positions can be made cyclically, such that each shifted SRS covers a new set of RBs, e.g. the predefined pattern can be defined such that the UE cycles through (all or a subset of) the Δ+l different possible frequency domain positions in different subframes. This has an advantage in the signaling can be minimized.

A system configuration can, according to an embodiment, be utilized for providing such information implicitly. Here, different system configurations are assigned to utilize different frequency domain positions. For example in the prior art LTE Rel-10 system, table 1 shows that there are several configurations of C _SRS which apply the same value of _SRS0 .

Different configurations relating to the same value _SRS0 could thus be related to different frequency domain positions in a pre-defined manner. This could be achieved by either assuming the existing configurations C _SRS in the system and associating a configuration with a starting position TISTART ^or new

configurations could be added; C _SRS >7.

It is also understood by a person skilled in the art, that the invention also applies and can be implemented if the SRS bandwidth configurations C _SRS will be provided by UE-specific signaling in any future system release.

According to an embodiment of the invention, at least one frequency domain position being used for creating at least one shifted SRS according to the above described methods is explicitly provided to a UE by a signaled parameter. This has an advantage in that the eNodeB thereby gets a larger freedom in arranging the frequency domain positions since the

information relating to the frequency domain position is signaled by an independent parameter.

To explicitly provide the UE this information could, according to an embodiment, be achieved by signaling an integer-valued non-negative parameter x^ such that:

¾ ^P) = ( B/2J - m _SRS ,o/2)N _s ^R _c ^B + fcg? + (x^ - AM™ , (Eq . 7 ) where A may be a suitable chosen integer such that a positive and/or negative shift may be obtained. In one example, the same value for the parameter x^ is used for all antenna ports. An integer-valued non-negative parameter can, according to an embodiment of the invention, be provided by Radio Resource Control (RRC) layer signaling.

Thus, if 2 bits are used to encode 4 different frequency domain positions could be arranged. The parameter x^ could be independent of kf _c , thereby letting the eNodeB have full freedom to allocate transmission comb and starting position START independently.

The explicitly signaled parameter can, according to different embodiments, be an integer valued positive parameter being either UE specific or cell specific.

If the parameter is configured to be UE-specific, it is possible to assign different SRS positions to the UEs in a cell. The eNodeB may thus assure that all RBs in the carrier may be sounded, although a single UE will not sound all RBs in the carrier. If the parameter is configured to be cell-specific, this configuration then results in that less signaling is needed compared to a UE-specific configuration. Although it implies that certain RBs will not be sounded in a cell, it has the advantage that the SRS interference between cells could be reduced by allocating different SRS frequency domain positions to different cells. This will improve the performance of the system as better scheduling and link adaptation can be

expected. Furthermore, since all UEs apply the same shift in the cell, there will be no partial overlap of shifted SRSs and full orthogonality can be guaranteed.

According to an embodiment of the invention, The explicitly signaled parameters can be signaled in a Physical Downlink Control Channel (PDCCH) . In the prior art LTE Rel-10 system, SRS transmission can be triggered by explicit bits contained in DL assignments or UL grants carried in the PDCCH. This is referred to as trigger type 1 in LTE Rel-10, i.e., aperiodic SRS transmission.

According to an embodiment of the invention, additional bits are introduced in the PDCCH to indicate further information of the frequency domain positions of the shifted SRSs. With 2 such bits, 4 different frequency domain positions can be indicated, which is sufficient for the applying the creation of the extended SRS region, i.e. to applying the invention, to a prior art LTE Rel-10 system.

However, additional bits increase the control overhead in the system. Therefore, a number of embodiments of the invention relates to signaling not increasing the control overhead in the PDCCH. According to an embodiment, existing bits in the PDCCH are reused to indicate further information of the frequency domain positions of shifted SRSs. For example, for PDCCH DCI Format 4, 2 bits comprises a SRS request field and are used to

trigger SRS transmissions. There are also other DCI formats containing 1 bit SRS request field. Table 3 shows an example of the interpretation of the trigger bits. Thus the trigger bits determine which one of the 3 SRS configurations that should be applied.

Table 3

Here, information regarding the frequency domain position of the SRSs could be encoded by reducing the number of SRS

parameter sets. For example, if only the 1 ^st SRS parameter set is assumed, the values ^Λ 10' and ^Λ 11' could encode additional information relating to frequency domain positions TISTART f° ^r the 1 ^st SRS parameter set. To explicitly provide the UE this information could, according to another embodiment of the invention, be achieved by

utilizing signaling that reuses already existing bits in the PDCCH.

The selection of an RE set used within the extended SRS region, i.e. the selection of transmission comb, only corresponds to 1 bit of information. In the prior art LTE Rel-10 system, the transmission comb is signaled through a parameter k _TC G {0,1}, and —(p)

^■ offset /CQ is a function of k _TC . Thus, the bit conveyed by k _T can be reused and be associated to a frequency domain position n _START .

For example, if TISTART ⁼ 0 is used when k _c = 0 and n _START = Δ when kf _c = 1, the following expression applies:

¾ ^P) = (W - m _S RS,o) Vs ^R c ^B + ?) ?- (Eq. 8)

According to an embodiment of the invention, the independent parameter being utilized for explicit signaling makes use of unused code points in the PDCCH for encoding of the parameter. Thus, no additional bits are here introduced in the PDCCH but unused code-points in the PDCCH are reused for encoding frequency domain positions for the shifted SRSs.

The reuse of the unused code-points can be achieved by either restricting a usage of at least one field in the PDCCH, or performing a higher layer configuration of at least one field in the PDCCH.

If SRS is triggered by the PDCCH, functionality provided by some information fields may be discarded. For example, in LTE Rel-10, there is 1 bit in DCI Format 4 that determines the resource allocation type (single-cluster or multi-cluster) for the PUSCH. If the resource allocation is constrained to either type when the SRS request field is non-zero, the resource allocation bit could be used for encoding frequency domain positions of shifted SRS instead. That is, restriction of the usage of at least one field in the PDCCH is used for encoding frequency domain positions for the shifted SRSs. If SRS is triggered by the PDCCH, functionality provided by some information fields may be provided by higher layers, e.g., MAC or RRC signaling. For example, in LTE Rel-10, there is 1 bit in DCI Format 4 that determines the resource allocation type (single-cluster or multi-cluster) for the PUSCH. If the resource allocation type can be configured by higher layers, this bit in the PDCCH could be used for encoding frequency domain positions for the SRSs when the SRS request field is non-zero. The UE would then apply the resource allocation type as indicated by higher layer signaling when the SRS request field is non-zero. When the SRS request field is zero, the bit could be used to encode the resource allocation type as

originally defined for. In comparison to adding bits in the PDCCH, additional bits in the higher layer signaling is

typically not an issue.

According to an aspect of the invention, a method of an eNodeB for configuration and reception of a transmission of SRSs on an uplink carrier of the telecommunication system is provided. The configuration includes providing configuration

instructions relating to at least one shifted SRS to be

created to an UE . The UE the creates at least one shifted SRS by shifting the predefined frequency domain position for at least one of said predefined SRSs in accordance with the

instructions, thereby creating an extended SRS region. Then the eNodeB receives on said UL carrier a at least one shifted SRS, whereby at least one additional RB can be sounded.

Those skilled in the art should understand the foregoing

embodiments or part of the procedures may be implemented

through programs instructing related hardware means and the program can be stored on a computer readable storage media. Figure 4 schematically illustrates a telecommunication system 400 according to the invention. The telecommunication system

400 includes at least one eNodeB 410 and at least one UE communicating with each other over a radio interface 430 including UL and DL carriers .

In the eNodeB 410, the hardware means 411, being a computer, a processor, a DSP (Digital Signal Processor) , an ASIC

(application Specific Integrated Circuit) or the like, is connected to an antenna 413 receiving and transmitting signals over the radio interface 430. The hardware means 411 is, when being e.g. a processor, a DSP, a computer or the like, connected to a computer readable storage media 412. The computer readable storage media 412 includes ROM/RAM, soft discs, Compact Disk, etc., and is arranged for providing the hardware means 411 with instructions needed for performing the method of the invention, i.e. for performing the following steps of:

- providing configuration instructions relating to at least one shifted SRS to be created to an UE, whereby the UE creates at least one shifted SRS by shifting the predefined frequency domain position for at least one of said predefined SRSs in accordance with the instructions, thereby creating an extended SRS region; and

receiving on said UL carrier at least one shifted SRS, whereby at least one additional RB can be sounded.

In other words, according to an aspect of the invention, an eNodeB arranged for configuration and reception of a

transmission of Sounding Reference Signals is presented. The eNodeB includes a configuration entity, arranged for providing configuration instructions to the UE in the system. These instructions are relating to creation of at least one shifted SRS by shifting the predefined frequency domain position for at least one of the predefined SRSs, thereby creating an

extended SRS region including at least one additional RB being separate from the predefined SRS region. The eNodeB also

includes reception entity, arranged for receiving the at least one shifted SRS on the uplink carrier.

Correspondingly, in the UE 420, the hardware means 421, being a computer, a processor, a DSP (Digital Signal Processor) , an ASIC (application Specific Integrated Circuit) or the like, is connected to at least one antenna 423 receiving and

transmitting signals over the radio interface 430. The

hardware means 421 is, when being e.g. a processor, a DSP, a computer or the like, connected to the computer readable

storage media 422. The computer readable storage media 422 includes ROM/RAM, soft discs, Compact Disk, etc., and is

arranged for providing the hardware means 421 with

instructions needed for performing the method of the invention, i.e. for performing the following steps of:

creating at least one shifted SRS by shifting the predefined frequency domain position for at least one of the predefined SRSs, thereby creating an extended SRS region including at least one additional RB being separate from the predefined SRS region; and

- transmitting the at least one shifted SRS on the UL carrier.

In other words, according to an embodiment of the invention, a UE is arranged for performing transmission of SRSs. The UE includes a shift creating entity, which is arranged for

creating at least one shifted SRS by shifting the predefined frequency domain position for at least one of the predefined SRSs, thereby creating an extended SRS region including at least one additional RB being separate from the predefined SRS region. The shift creating entity can receive instructions from an eNodeB which is used in this creation. The US also includes a transmission entity, being arranged for transmitting the at least one shifted SRS on the UL carrier.

The UEs and eNodeBs of the invention can be adapted to perform any of the steps of the method of the invention involving the UE and eNodeB, respectively.

The different steps of the embodiments of the method of the invention described above can be combined or performed in any suitable order. A condition for this of course, is that the requirements of a step, to be used in conjunction with another step of the method of the invention, must be fulfilled.

As is obvious for a skilled person, a number of other

implementations, modifications, variations and/or additions can be made to the above described exemplary embodiments. It is to be understood that the invention includes all such other implementations, modifications, variations and/or additions which fall within the scope of the claims.