RU2237364C2 - Device and method for controlling transmitting antenna array for shared use of downlink physical channel in mobile communication system - Google Patents

Abstract

FIELD: mobile communication systems; soft service transmission.

SUBSTANCE: proposed method and device are used to control transmitting antenna array by finding optimal weighting coefficient for separation circuit of shared downlink physical channel during soft service transmission with aid of subscriber equipment in soft service transmission area. To this end mobile communication system subscriber equipment, in case it enters soft service transfer area, finds information about weighting coefficient for separated physical channel and shared downlink physical channel depending on separated physical channel and shared downlink physical channel signals receiver from B centers and transfers definite information about weighting coefficient to B centers. Then the latter determine weighting coefficients of separated physical channel and shared downlink physical channel signals which should be transmitted to subscriber equipment depending on feedback information received from the latter, and definite weighting coefficients are accordingly transferred to subscriber equipment together with separated physical channel and shared downlink physical channel signals.

EFFECT: facilitated control of transmitting antenna array.

2 cl, 15 dwg

Description

Field of Invention

The present invention relates, in General, to a mobile communication system, and more specifically to a device and method for controlling a transmitting antenna array (PAR (TXAA)) for a shared physical channel downlink (SIFK-NLS (PDSCH)) in the field of soft transmission maintenance (MP (SHO)).

BACKGROUND OF THE INVENTION

The Shared Downlink Physical Channel (CIFK-NLS), typically used in the 3rd generation Mobile Broadband Code Division Multiple Access (W-CDMA) asynchronous mobile communication system, refers to a channel that shared by multiple subscriber equipment (AA (UE)). SIFK-NLS is a channel assigned to transmit packet data or high-speed data to AA in a 10 ms radio frame and which is usually used by multiple AAs. SIFK-NLS allows you to change the data rate in the frame, as well as adjust the weight coefficient on the transmitting antenna array and control the power in the interval, like a dedicated channel (VK (DCH)) installed between node B and AA in the W-CDMA system. A radio frame, the basic unit (block) for transmitting signals in the W-CDMA system, has a duration of 10 ms, and each radio frame consists of 15 intervals. In addition, SIFK-NLS is a channel for transmitting user data only. When an SIFK-NLS is assigned to AA for power control over the SIFK-NLS, a dedicated downlink physical channel (VFC-NLS (DL-DPCH)) is assigned to AA in conjunction with SIFK-NLS. In this case, the VFK-NLS becomes a channel for controlling the power of the SIFK-NLS. On SIFK-NLS you can continuously transmit information to one AA for many frames. On the other hand, on SIFK-NLS it is possible to transmit to AA within only one frame. In addition, the frame transmission time for multiple AAs is determined by scheduling at the upper level.

The SIFK-NLS structure and the VFC-NLS structure assigned to AA in conjunction with the SIFK-NLS are described below with reference to FIGS. 1A and 1B. Fig. 1A depicts a SIFK-NLS structure used in a mobile communication system, and Fig. 1B depicts a SFC-NLS structure designated by AA in conjunction with SIFK-NLS.

As shown in figa, the radio frame 101 SIFK-NLS has a duration of 10 ms and consists of 15 intervals, "Interval No. 0-interval No. 14". Each interval, for example, “Interval No.i” (103), has a duration equal to 2560 elementary signals, and the amount of information transmitted in “Interval No. 1” 103 is inversely proportional to the coefficient of expansion of the spectrum (KRS (SF)) used for the SIFK- intervals NLS. The cattle has values from 4 to 256, and the data with the transmitted information is expanded over the spectrum in accordance with the value of the cattle. On SIFK-NLS only user data is transmitted.

Further, as shown in FIG. 1B, when using the SIFK-NLS shown in FIG. 1A, the VFK-NLS associated with the SIFK-NLS is assigned to the corresponding AA using the Node B. The radio frame 111 of the VFK-NLS also consists of 15 intervals, "Interval No. 0 - interval No. 14", and each interval, as shown in FIG. 1B, consists of bits 112 "Data 1", bits 113 "Transmission power control" (TPC), bits 114 "Format combination indicator transmission "(TFCI), bits 115" Data 2 "and bits 116" Pilot signal ". Each interval VFK-NLS can have different structures in accordance with the values of the duration "Data 1", UMP, IKFP, "Data 2" and "Pilot signal".

Bits 112 "Data 1" and bits 115 "Data 2" are transmitted over a dedicated physical downlink data channel (DL-DPDCH), and the HD-PDL transmit user data and signaling information from the upper layer. SAR 113, IKFP 114 and pilot signal 116 are transmitted over a dedicated physical downlink control channel (DL-DPCCH). SAR 113 is a field for transmitting a command for controlling the transmit power of uplink channels transmitted from AA to node B; IKFP 114 - a field for transmitting a codeword indicating that transport channels having different data rates are transmitted through the VFC-NLS; and pilot signal 116, a field for indicating permission of the AA to measure the transmit power of the downlink signal to control power from the received downlink signal. In this case, a “transport channel” refers to a channel that serves to connect a physical channel and actually transmit data to the upper layer.

In the W-CDMA system for a feedback feedback antenna array for SIFK-NLS, the AA receiving the VFC-NLS 111 sends to the node B weight information obtained by measuring the common pilot channel (CPICH) received from the node B. That is, after receiving the DIC signal transmitted from node B, AA compensates for its phase difference in such a way as to determine the weight coefficient necessary for the maximum received power level. The weighting information created depending on the specific weighting factor is transmitted to the Node B, and before the transmission, the Node B uses the respective weights for the respective antennas for the WFK-NLS signal transmitted to AA, depending on the weighting information of the WFK-signal NLS and / or SIFK-NLS adopted from AA.

Below, with reference to FIG. 2, a description will be given of the signal flows on the downlink and uplink for the case where the AA receiving the SIFK-NLS signal is in the soft handoff area. Figure 2 shows the signal flows on the downlink and uplink for the case when the AA receiving the SIFK-NLS signal is in the soft handoff area, in which only two nodes B are considered for simplification.

In the process of soft handoff (MP (SHO)), when AA leaves the current node B1, which is in communication with AA, and at the same time moves to the area where it can receive signals from an adjacent new node B2, AA does not receive signals not only from the current node B1, but also from the new node B2. In this state, if the quality (or level) of the signal received from node B1 is less than a predetermined threshold, then AA disconnects the channel established with node B1, and then establishes a new channel with node B2, providing high-quality signals and thus performing the handover process . By doing this, you can support the call without interruption.

As shown in figure 2, the node B1 201, which is currently in communication with AA 211, transmits SIFK-NLS and VFC-NLS signals associated with SIFK-NLS to AA 211. However, the node B2 203 transmits only over the channel VFK-NLS in AA 211 when AA 211 moves to the MP region located between node B1 201 and node B2 203. The set of all nodes B installed to transmit signals to AA 211 existing in the MP region is called an “active set”. That is, the B1 201 node transmits via the VFK-NLS and SIFK-NLS channels to AA 211, and the B2 203 node is again added to the active set and transmits only through the VFK-NLS channel to AA 211. The AA 211 broadcasts the VFK-VLS to node B1 201 and node B2 203 indiscriminately. In the prior art, when AA 211 enters the MP domain, AA 211 receives all OPC signals from node B1 201 and node B2 203 and measures OPC signals in order to select primary node B from nodes B. AA 211 transmits a temporary ID (ID) of the node B, designated as the primary node B, in the feedback information field (IOS (FBI)) of the VFK-VLS (UL_DPCH). IOS has 2 fields in length, as shown. The S field in the IOS AA 211 transmits to the Node B when location pick diversity transmission (PRSM (SSDT)) is used. Field D in the IOS AA 211 transmits to node B when transmit antenna diversity is used. Field S consists of 0, 1, or 2 bits. If the S field consists of 0 bits, then this means that the PRVM is not used. If the PRVM is used, then the IOS field transmits a codeword, which is a temporary identifier for the ID of the primary node B. Field D consists of 0, 1, or 2 bits. If the D field consists of 0 bits, then this means that transmit antenna diversity is not used. In the case of using 1 bit, transmit antenna diversity is used in conjunction with the PCS, and in the case of 2 bits, only transmit antenna diversity is set.

When AA 211, receiving the SIFK-NLS signal from node B1 201, is in the MP region, the problem is that AA 211 receives both SIFK-NLS and WFC-NLS signals from node B1 201, but from node B2 203 it receives only VFK-NLS. In this case, the typical reason that SIFK-NLS does not support MP is, in comparison with VFK-NLS, that SIFK-NLS transmits data at a relatively high transmission rate, thus consuming more channel resources of node B. As a result, the throughput is reduced . In addition, the III-CDMA mobile communication system may have a problem with timing due to the lack of synchronization between nodes B. In order to support the MP, SIFK-NLS, which is shared by many AAs, requires a detailed scheduling for times where It is used by appropriate AA. Given the complexity of the development of scheduling, it is difficult to transmit a SIFK-NLS signal from a new node B to AA.

VFC-NLS transmitted from node B1 201 and node B2 203, are received in AA 211 and then subjected to soft association. In this case, “soft combining” refers to combining signals received in AA in various ways. Therefore, by calculating the phase difference between the OPC signals received from nodes B and performing subsequent compensation of the phase difference, it is possible to reduce the effects of fading and noise that affect the signals received in AA 211. Soft combining is only available when AA 211 receives one and the same information from other nodes B. However, when the AA 211 receives various information from nodes B, the received information, although it undergoes soft combining, will be recognized as a noise component, leading to the appearance of a noise component at the signal.

In the analysis of the HFC-NLS analysis, the downlink signals transmitted to AA 211 from the respective nodes B, that is, the node B1 201 and the node B2 203, undergo soft combining, with the exception of bits 113 of the SAR shown in FIG. 1B. The reason that SAR 113 is analyzed separately, and not analyzed by soft combining, is because SPS received in AA 211 from the corresponding nodes B may differ from each other, since the signal received at the node B1 201 from AA 211 has a high level, while the signal received at node B2 203 from AA 211 is low or vice versa due to movement of AA 211. Therefore, SAR 113 is analyzed using a separate SAR analysis algorithm for a plurality of B nodes, and not by soft combining.

Above, with reference to FIG. 2, a description has been given of downlink and uplink signals for the case where AA is located in the MP region. The operation of the transmitting antenna array (TxAA) supporting the MP will be described below with reference to Fig.3.

Figure 3 shows the operation of a transmitting antenna array using the known soft handoff scheme. As shown in FIG. 3, when AA 311 is located in the MT region during a call, node B1 301 and node B2 303 transmitting signals to AA 311 reduce their transmit power for soft handoff when serving a call, and at the same time AA 311 calculates the weights depending on the phase difference between the OPC signals that are transmitted from both nodes B in order to maximize the signal-to-noise + noise ratio (SINR), and then feeds the weights back to node B1 301 and a new node B2 303 according to VFK-NLS and SIFK-NLS node V1 301 and a new one la 303 B2.

AA 311 performs a soft combining of signals received from node B1 301 and node B2 303 with weights that are transmitted to nodes B in the feedback information field (FBI) of a dedicated uplink physical channel (UL-DPCH) 3), and then determines the weights in order to maximize the SINR of the received signals after soft combining. That is, since AA 311 performs a soft combining of the signals received from the node B1 301 and the node B2 303, and determines the feedback weights of the received signals in order to maximize the SINR, a known method of applying the optimal weight coefficient for SIFK-NLS, in which only one node B located in the MP region, for example, node B1 301 having the highest received signal level, must transmit signals, has the following disadvantages.

If AA 311 is not located in the MP region, then the weights of the transmitting antenna for SIFK-NLS and VFC-NLS transmitted to AA 311 are identical to each other. In other words, the weight coefficient of the transmitting antenna array for SIFK-NLS is determined in conjunction with VFC-NLS. A change in the phase ratio and the size of these two antennas for the VFK-NLS leads to an equivalent change in the weights, since the SIFK-NLS is transmitted on the same channel. For this reason, the weight coefficient for the associated SFC-NLS is used for the weight coefficient of SIFK-NLS.

However, if AA 311 is located in the MP region, the transmitting antenna arrays for the VFK-NLS and SIFK-NLS are determined in the same way using weighting coefficients determined by measuring the phase difference between the UPC signals not only from the node B transmitting the SIFK-NLS to AA 311 , but also from other nodes B registered in the active set. In particular, in the description of FIG. 3, the weight coefficient of the transmitting antenna array for SIFK-NLS is determined taking into account the conditions of the channel between AA 311 and the node B with the highest level of the received signal, that is, node B1 301, while the weight coefficient of the transmitting antenna array for the IFC -NLS is determined taking into account the conditions of the channel not only in the node B1 301, which has the highest level of the received signal, but also in the node B2 303 in the active set AA 311.

In the above description, it is assumed that the weighting coefficient of the transmitting antenna for SIFK-NLS according to the known MP design has the same meaning as the weighting coefficient of the transmitting antenna for SFC-NLS, resulting in the aforementioned problem. That is, in the MP region, the weight coefficients transferred from nodes B to AA 311 are determined taking into account not only the conditions of the channel between AA 311 and node B1 301, but also the conditions of the channel between AA 311 and node B2 303. Thus, if incorrect weights, SIFK-NLS will have a weight coefficient different from the weight coefficient for the actual transmitting antenna array. Therefore, the method for applying the same weight to the transmitting antenna arrays, which is used for the VFK-NLS and SIFK-NLS not in the MP region, cannot be used in the MP region. Therefore, there is a need for a device and method for the correct control of the transmitting antenna array for SIFK-NLS in the field of MP.

SUMMARY OF THE INVENTION

The objective of the present invention is to create a device and method for controlling a transmitting antenna array for SIFK-NLS using AA in the field of MP.

Another objective of the present invention is to provide a device and method for controlling a transmitting antenna array for SIFK-NLS by determining the optimal weight coefficient for the SIFK-NLS diversity scheme using AA in the MP region.

An additional objective of the present invention is to provide a device and method for controlling a transmitting antenna array for SIFK-NLS using the IOS field D of the IFCS-NLS using AA receiving SIFK-NLS in the MP region.

Another objective of the present invention is to provide a device and method for controlling a SIFK-NLS transmit antenna array using various transmit antenna antennas for SIFK-NLS so as not to be coupled to the WFC-NLS by AA receiving SIFK-NLS in the field of MP.

Another objective of the present invention is to create a device and a method in which a transmitting antenna array is used in the M region in the node B transmitting SIFK-NLS and VFK-NLS, and in other nodes B transmitting only the VFC-NLS open-loop transmit antenna diversity scheme, such as PVRP (open-loop transmit diversity (STTD); space-time diversity transmit antenna diversity based on block coding).

Another objective of the present invention is to create a device and a method in which a transmitting antenna array is used in the M region in the node B transmitting the SIFK-NLS and VFK-NLS, and in other nodes B transmitting only the VFC-NLS single antenna without transmit antenna diversity scheme.

Another objective of the present invention is to provide a method for switching transmit diversity antennas corresponding to nodes B when an AA receiving an SIFK-HLS undergoes a handoff of the SIFK-HLS in the MP domain.

Another objective of the present invention is to provide a method for transmitting feedback information for SIFK-NLS and feedback information for BFCS (DPCCH) on separate BFCS-NLS in the case where an AA receiving SIFK-NLS is located in the MP region.

Another object of the present invention is to provide a method for correctly managing an advanced SIFK-NLS (P-SIFK-NLS) by determining whether data on the P-SIFK-NLS from the same node B is received based on the “time sequence” in areas of MP.

Another objective of the present invention is to provide a method for preliminary recognition of the SIFK-NLS transmission time and the separate application of the weight coefficient to the node B transmitting the SIFK-NLS, so that the node B transmitting the SIFK-NLS operates in the transmit antenna array mode in the field of MP.

To solve the aforementioned and other problems, a device "Node B" has been created, which has at least two antennas for controlling the diversity of data transmitted through the antennas. The device comprises a first spectrum extender for spectrally expanding the first data and outputting the first spread spectrum signal, a second spectrum extender for spectrally expanding the second data and output the second spread spectrum signal; a first multiplier for multiplying the first weighting factor for the first antenna by a first spread spectrum signal from the first spectrum extender and outputting a first weighted spread spectrum signal; a second multiplier for multiplying the second weight coefficient for the second antenna by a first spread spectrum signal from the first spectrum extender and outputting a second spread spectrum weighted signal; a third multiplier for multiplying the third weight coefficient for the first antenna by a second spread spectrum signal from the second spectrum extender and outputting a third weighted spread spectrum signal; a fourth multiplier for multiplying a fourth weighting factor for the second antenna by a second spread spectrum signal from the second spectrum extender and outputting a fourth weighted spread spectrum signal; a first adder for adding a first spread spectrum weighted signal to a third spread spectrum weighted signal and transmitting the total signal through the first antenna; a second adder for adding a second spread spectrum weighted signal to a fourth spread spectrum weighted signal and transmitting the total signal through a second antenna and a weight generator to determine the first to fourth weight coefficients from the feedback information received from the user equipment (AA), and filing the first to fourth weights, respectively, in the first to fourth multipliers.

Brief Description of the Drawings

The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description and the accompanying drawings, in which:

figa depicts the structure of SIFK-NLS used in a mobile communication system;

figv depicts the structure of the VFC-NLS designated AA in conjunction with SIFK-NLS;

figure 2 depicts the signal flows on the downward and upward communication lines for the case in which the AA receiving SIFK-NLS located in the area of soft handoff;

figure 3 depicts the operation of the transmitting antenna array using the known scheme of soft handoff;

4A depicts a transmit diversity control process according to a first embodiment of the present invention:

4B depicts a transmission diversity control process according to a second embodiment of the present invention;

4C shows a transmission diversity control process according to a third embodiment of the present invention;

Fig. 4D depicts a transmission diversity control process according to a fourth embodiment of the present invention;

4E depicts a transmission diversity control process according to a fifth embodiment of the present invention;

FIG. 4F shows the internal structure of a channel meter of a transmitting antenna array for performing various embodiments of the process of the present invention;

5 is a flowchart of a procedure for a transmission diversity control process shown in FIG. 4A;

6 depicts an AA structure for performing a transmission diversity control process shown in FIG. 4A;

FIG. 7 depicts an AA structure for performing the transmission diversity control process shown in FIG. 4D;

Fig. 8 depicts the structure of a node B for performing the transmission diversity control process shown in Fig. 4D; and

FIG. 9 is a flowchart for a SIFK-NLS / P-SIFK-NLS signaling procedure based on a transmission timing according to a seventh embodiment of the present invention.

Detailed Description of a Preferred Embodiment

The following is a description of a preferred embodiment of the present invention with reference to the accompanying drawings. In the following description, known functions or constructions are not described in detail in order to avoid unnecessarily complicating the invention with unnecessary details.

FIG. 4A illustrates a transmit diversity control process according to a first embodiment of the present invention. FIG. 4B illustrates a transmit diversity control process according to a second embodiment of the present invention. FIG. 4C illustrates a transmit diversity control process according to a third embodiment of the present invention. FIG. 4D illustrates a transmit diversity control process according to a fourth embodiment of the present invention. 4E illustrates a transmit diversity control process according to a fifth embodiment of the present invention. FIG. 4F shows the internal structure of a channel meter of a transmitting antenna array for performing various embodiments of the present invention.

In the description of FIGS. 4A-4F, a number of nodes B registered in the active set are shown for simplification at 2. Node B, which is used in the W-CDMA asynchronous system, works in the same way as the base station transceiver subsystem (BTS) in the synchronous system SDMA-2000.

As shown in FIG. 4A, node B1 401 (node B currently in communication with AA 411) transmits signals through the WFK-HLS and SIFK-HLS to AA 411. Node B2 403 (node B is again added to the active set AA 411) transmits only via VFK-NLS to AA 411, when AA 411 is located in the MP region. AA 411 receives signals SIFK-NLS and VFK-NLS from node B1 401, but it only receives a signal from VFC-NLS from node B2 403. AA 411 transmits feedback information (IOS) included in the VFC-VLS to node B1 401.

On figa AA 411 is located in the region of the MP and allows the new node, that is, the node B2 403 in the active set, to transmit the signal VFK-NLS in space-time diversity transmission with block coding (PVRP) or in single antenna mode (OA (SA)), even with the availability of the transmitting antenna array mode (PAR (TxAA)).

PVRP, a type of open loop antenna diversity scheme, is not subject to feedback, so that there is no loss of SIFK-NLS signal due to soft combining along the OPC from both nodes B. In addition, since there is only one antenna in OA mode, then explode is not used. Among the information of the VFKU-NLS, the information on the weight coefficients of the SAR in the IOS field D is actually valid only for the B1 401 node. Therefore, the information on the weight coefficient is calculated depending on the DPC transmitted from the B1 401 node. Therefore, in the well-known circuit, the AA 411 allows the current node B1 401 and node B2 403, newly added to the active set, transmit the PAIR, calculates weighting factors from information determined by combining information received from node B1 401 and node B2 403, and applies the calculated weighting factors as weight SIFK-NLS coefficients of node B1 401. Therefore, the present invention allows to solve the problem that is manifested in the known system in that the operation of the SAR for SIFK-NLS does not show what is required in the MP region due to differences between the actual weight coefficients and the calculated weight coefficients when SIFK-NLS, the transmit antenna weight of which is set to the same value of these VFC-NLS, is used in the same way both in node B1 401 and in node B2 403.

Therefore, when SIFK-NLS transmitted from node B1 401 was completely serviced to node B2 403, the VFK-NLS from node B2 403 transmits in PAR mode together with SIFK-NLS, as shown in FIG. 4A, and VFC-NLS , which remains in node B1 401, switches from the PAR mode to the PVRP or OA mode. Meanwhile, if the OA mode and the PVRP mode can be used together in the same node B, then it is preferable to use the PVRP mode rather than the OA mode. This is why the PVRP scheme has a diversity effect that is the same or better than that of the SAR scheme, provided that the data rate is not extremely low. Even at a low data transfer rate, the PVRP scheme, compared with the PAR scheme, experiences a decrease in the SINR by a maximum of 2 dB, but it has a simpler hardware structure.

Meanwhile, in the first embodiment of the present invention, as shown in table 1, in which the switching operation AA 411 is shown using tabular information at the receiving point SIFK-NLS in the field of MP, VFC nodes B, different from the serving cell SIFK-NLS transmit signals in PVRP or OA mode, although SIFK-NLS and VFK of the serving cell SIFK-NLS continue to work in PA mode. That is, AA 411 receives IKFP VFK, IKFP, including information about the beginning of the transfer of SIFK-NLS from the serving cell SIFK-NLS, and 5 intervals before transmitting SIFK-NLS. After receiving the IFPC from the serving cell, SIFK-NLS AA 411 can recognize that SIFK-NLS will be received before its transmission. Therefore, AA 411 separately creates weights that are correct only for the serving SIFK-NLS cell at predetermined time intervals before receiving SIFK-NLS and then feeds back the created weights using IOS VFK-VLS.

More specifically, AA in the field of MP accepts an IFC or an IFC with SIFK-NLS in accordance with the transmission condition. After receiving SIFK-NLS along with the IFC from node B, AA feeds back the IOS of the VFC-VLS to the corresponding nodes B in the active set. Further, the Node B transmitting the VFC including the SIFK-NLS continues to operate in the PA mode using IOS information, while the other nodes B transmitting only the VFC do not use the IOS information and allow their VFC to operate in the STD or OA mode. OA mode includes a PA mode where diversity gain is not obtained without taking into account the IOS or using the previous value. In addition, after the SIFK-NLS transmission is completed, the non-SIFK-NLS serving cell mode operating in PVRP or OA mode returns to the PAIR mode, and AA returns to the state that existed before the SIFK-NLS transmission, where AA calculates weighting factors using the phase difference between the DPC transmitted from nodes B, and then feeds back the calculated weights to nodes B.

In this case, the PVRP scheme is a transmission diversity scheme for open-loop antennas, and if the PVRP coding is performed on a data signal A, which has a format constructed so that the symbols S ₁ and S _{2 are} sequentially input into periods T ¹ and T, respectively ² encodings for transmit diversity, then successive S ₁ S ₂ characters are output as S ₁ S ₂ through the first antenna and S $\genfrac{}{}{0ex}{}{\text{*}}{\text{1}}$ S $\genfrac{}{}{0ex}{}{\text{*}}{\text{2}}$ through the second antenna. The above coding of the STDT symbols will be described again in terms of channel bits. As described in PVRP encoding, if we assume that the symbols S ₁ and S ₂ received during the coding periods for transmit diversity are generated using channel bits b ₀ b ₁ and b ₂ b ₃ , respectively, then the received symbols S ₁ S ₂ become channel bits b ₀ b ₁ b ₂ b ₃ . After the channel bits b ₀ b ₁ b ₂ b ₃ are subjected to PVRP encoding, the channel bits b ₀ b ₁ b ₂ b ₃ (S ₁ S ₂ ) are output through the first antenna and the channel bits -b ₂ b ₃ b ₀ -b ₁ (-S $\genfrac{}{}{0ex}{}{\text{*}}{\text{2}}$ S $\genfrac{}{}{0ex}{}{\text{*}}{\text{1}}$ ) are output through the second antenna. In this case, the first antenna is an antenna emitting a reference signal, and the second antenna is a diversity antenna.

As shown in FIG. 4B, if AA 431, to which a downlink channel is connected, including SIFK-NLS, is introduced into the MP region, then the VFK-NLS transmits in PVRP or OA mode in node B1 421 and in node B2 423 The SIFK-NLS signal transmitted only by means of the B1 421 node is transmitted in the PAIR mode. That is, when using the SAR only for SIFK-NLS, which is used for data transmission, despite the deterioration of the performance of the VFK-NLS, the total loss of the SIFK-NLS signal is reduced, which ensures reliable data transmission. In this case, the dedicated pilot channel included in the WFK-NLS from node B2 421 should additionally include information for demodulating the SIFK-NLS signal. A method for additionally including information for demodulating SIFK-NLS, as well as for a dedicated pilot channel, includes time division multiplexing (TDM) / code division multiplexing (CDM) / frequency division multiplexing ( FDM (FDM)) / space-time coded Mr (DM) / additional methods or methods of changing the field. It is most preferable to consider the RTM, given the fact that an AA receiving SIFK-NLS has a low data rate.

In the second embodiment of the present invention, which is illustrated in table 2, in which the switching operation AA 431 is shown using tabular information at the time of receiving SIFK-NLS in the region of the MP, the signal VFC-NLS is transmitted in PVRP or OA mode in the node B1 421 and in the node B2 423, while the IFK-NLS signal transmitted only by the B1 421 node is transmitted in the PAR mode using the VFC-VLS IOS. In this case, AA 431 receives the IFPC, which includes information about the start of transmission from the serving SIFK-NLS cell, 5 intervals before transmitting the SIFK-NLS signal and then recognizes that the SIFK-NLS will be received before it is transmitted. Therefore, AA 411 creates weights that are correct only for the serving SIFK-NLS cell at predetermined time intervals before receiving the SIFK-NLS and then feeds back the created weights.

In addition, if the SFC signal is received only after the SIFK-NLS transmission is completed, AA returns to the state that occurred before the SIFK-NLS transmission.

As shown in FIG. 4C, if AA 451 receiving a SIFK-NLS signal from node B1 441 enters the MP region, then node B1 441 transmitting SIFK-NLS is set to PVRP or OA, even though this SIFK -NLS worked in PAR mode. Of course, in this case, the VFK-NLS operates in the PAR mode both in the B1 441 node and in the B2 443 node. The SIFK-NLS will show the best performance in the PAR mode in comparison with the PVRP or OA mode. However, in the field of MP, since the PAIR scheme uses weights calculated from two nodes B, that is, node B1 441 and node B2 443, these weights differ from the weights that will actually be applied, thus leading to the problem of using incorrect weights coefficients, and, in addition, there is a feedback error and a delay error, which degrades the performance compared to the OA circuit. Therefore, it is preferable to use SIFK-NLS in PVRP or OA mode, and not in PAR mode. However, in this case, when using steam for IFC, you can get the best characteristics for IFC, which has a high permeability and quality of service (QoS).

In the third embodiment of the present invention, illustrated in table 3, in which the switching operation AA 451 is shown using tabular information at the time of receiving SIFK-NLS in the field of MP, the signal VFC-NLS is transmitted in PAIR mode in node B1 441 and in node B2 443, whereas SIFK-NLS transmitted only by the B1 441 node is transmitted in PVRP or OA mode. In this case, AA 451 calculates the weighting coefficients depending on the phase difference between the DPC signals transmitted from the nodes In the same way. In addition, if the WFC signal is received only after the completion of the SIFK-NLS signal transmission, AA returns to the state that occurred before the SIFK-NLS transmission.

As shown in FIG. 4D, if AA 471 is included in the MP domain, AA 471 creates an additional separate IOS field No. 2 for SIFK-NLS in VFKU-VLS and transfers the created IOS field No. 2 to node B1 461. That is, AA 471 calculates two different weight coefficients and transfers the created weight coefficients using the IOS field No. 1 for the VFC and the IOS field No. 2 for the SIFK-NLS in the VFC-VLS. A method for additionally creating an IOS field includes RTM / FIBC / MRF / additional methods for changing the field. It is preferable to use the RTM, given that the AA receiving the SIFK-NLS has a low data rate.

The method of highlighting the IOS field in the IOS field No. 1 and in the IOS field No. 2 by multiplexing the RTM is presented in table 5. In the known method presented in table 4, one IOS field is used, so that the values of the weight symbols I and Q are alternately transmitted on a two-interval basis . However, in Table 6, according to an embodiment of the present invention, two symbols are continuously transmitted according to the law I ₀ , I ₁ , Q ₀ , Q ₁ . In this case, I ₀ + Q ₀ is the PAIR weight symbol for the SFC-NLS, and I ₁ + Q ₁ is the PAIR weight symbol for the SIFK-NLS. Table 5 assumes that the ratio of the information on the weight coefficients of the VFK-NLS to the information on the weight coefficients of the SIFK-NLS is 1: 1. The ratio can be changed in accordance with the operating mode and channel conditions. In addition, Table 6 shows the interval format used when the weights of the various nodes B are sent using the SIFK-NLS IOS field. In this case, it is necessary to additionally set the field for transmitting the weight coefficients of the couple in the VFKU-VLS. An additional field is implemented using the PRVM field (IOS field S) or the pilot signal field.

In the fourth embodiment of the present invention, which is illustrated in table 7, in which the switching operation AA 471 is shown using tabular information at the time of receiving SIFK-NLS in the field of MP, IOC ₁ for VFC-NLS, which is transmitted using node B1 461 and node B2 463, and IOS ₂ for SIFK-NLS, which is transmitted only with the help of node B1 461, are additionally fed back using MRI / MKP / MRK / additional methods or methods of changing the field. In addition, if the WFC is accepted only after the completion of the SIFK-NLS transmission, then AA returns to the state that occurred before the transfer of the SIFK-NLS.

As shown in FIG. 4E, if AA 491 enters the MP region, that is, if the SIFK-NLS transmitted by the B1 481 node enters the MP region, the method of applying the transmission weights for the SIFK-NLS works the same way as the known method , but it identifies the primary node B, using the PRVM signaling, and then determines whether to increase or maintain the transmit power SIFK-NLS before transmission. Of course, weights for transmit diversity are used using SIFK-NLS, as well as VFC-NLS at two nodes B in the same manner as in the known method.

The PRVM signaling should be used not only when the PRVM is used, but also when the VFK-NLS, including SIFK-NLS, enters the MP region. After receiving information about the main cell through the PRVM signaling, the B1 481 node transmits a SIFK-NLS signal without an additional increase in transmit power. After receiving information about the non-core cell, node B1 481 applies the power change to the SIFK-NLS signal before transmission. To change the transmit power, a change in transmit power is used more than when SIFK-NLS uses the PAIR scheme. In conclusion, the transmit diversity offset for the OA scheme, the change in transmit power for the STD scheme, and the change in transmit power for the SAR scheme must be set so as to have independent values in accordance with the SIFK-NLS transmission diversity mode.

The operating principle of the PRM will be described below. In the PRMM, AA 491, located in the MP area, assigns temporary IDs (identifiers) to the corresponding nodes B in its active set, that is, node B1 481 and node B2 483, and then selects node B that better matches the quality of the received signal AA 491 among nodes B. Only the selected node B, for example, node B1 481, transmits the VFKPD-NLS to AA 491, and node B2 483, with the exception of the selected node B1 481, transmits only the VFKU-NLS to AA 491, thereby reducing the signals (interference) generated when all nodes In the active set are working on maintaining the MP. In the PRVM, the node B transmitting the VFKPD-NLS is called the primary node B, and the primary node B is periodically updated depending on the information measured using AA 491. In order to update the primary node B, AA 491 transmits a temporary ID of the primary node B to other B nodes in active sets.

A method for controlling the transmit power of an SIFK-NLS, in which a transmit diversity scheme using a PRM signaling is applied, will again be described in detail with reference to FIG. 4E. After receiving the DIC signals transmitted from the node B1 481 and the node B2 483, AA 491 compares the pilot signal levels of the received DSC signals and determines the primary node B depending on the obtained comparison results. In addition, AA 491 transmits a temporary ID pre-set for a specific primary node B to other nodes B, that is, to node B2 483. In FIG. 4E, node B1 481 is node B transmitting the HFC-NLS and SIFK-NLS to AA 491, and the node B2 483 is the node B, newly added to the active set, which transmits only the VFK-NLS in AA 491.

If AA 491 transmits a temporary ID for the primary node B, then node B1 481 determines the transmit power of the SIFK-NLS using the bits of the UMP VFK-NLS, and transmits signals with normal transmit power, taking into account that the influence of PAW weighting factors will be minimized. That is, to increase or decrease the SIFK-NLS transmission power is determined depending on the SAR bits transmitted using AA 491. As a result, when the B1 481 node becomes the primary node B, the transmission power control operation including the SIFK-NLS PAR operation performed in the same manner as when AA 491 is not located in the MP region.

If node B1 481, which was serviced as primary node B, is re-defined as secondary node B, and node B2 483, which was serviced as secondary node B, is re-defined as primary node B, then node B1 481, which estimates that the distance from AA 491 has increased or channel conditions are poor, applies a fixed change in transmit power to SIFK-NLS transmit power and transfers it to AA 491. After that, for a period where information regarding primary node B is updated, node B controls the SIFK-NLS transmit power depending spine of the TPC bits transmitted by the UE 491. However, it should be noted that when the TxAA scheme is used for the DL-SIPA in MP field must use different values for the fixed transmission power changes according separation methods.

The following describes a transmission diversity control method according to a sixth embodiment of the present invention. In a sixth embodiment of the present invention, if the AA receiving the SIFK-NLS is located in the MP region and the node B transmitting the SIFK-NLS signal transmits the SIFK-NLS using the antenna diversity in the closed loop transmission, the AA further assigns a new signal VFKU-NLS (UL-DPCCH). In this case, the VFKU-NLS signal transmitted to node B when AA is the first to use SIFK-NLS is called "VFKU-NLS1" ("UL-DPCCH1"), and the additional VFKU-NLS added again when AA is located in the MP region , is called "VFKU-NLS2" ("UL-DPCCH2").

In accordance with the 3rd generation mobile communication standard (W-CDMA standard), VFKU-NLS, used by AA, are expanded in the spectrum with the help of the first orthogonal code with variable coefficient of spreading (OVSF), that is, the OCR code with all 1-coded bits, among OPCR codes 256 KRS = 256, having a length of 256, is transmitted using AA, if necessary, on the Q channel. The reason that the VFKU-NLS is transmitted on the Q channel is to continuously transmit the VFKU-NLS even in the case where AA does not have communication data for uplink transmission th line after the call is set up, according to the W-CDMA standard, thereby preventing intermittent transmission of the uplink signal and therefore electromagnetic interference. A dedicated physical uplink data channel (UL-DPDCH) transmitted together with the VFC-NLS can use a spreading factor of 4 to 256. A maximum of 6 VFC-VLS can be transmitted. When using all 6 VFKPD-VLS, the coefficient of expansion of the spectrum of KRS = 4 is chosen: 3 VFKPD-VLS are transmitted on channel I and the remaining 3 VFKPD-VLS are transmitted on channel Q. Since the data received on channel I and the data received on channels Q , it is possible to analyze in the receiver independently of each other, there is no interference between the VFKPD-VLS caused by the use of the same OKR code in channel I and Q channel. When using the new additional VFKU-NLS AA, it is possible to determine the OKR code that will be used for the VFKU -NLS in various ways.

As a first example, the case when the current VFKU-NLS is installed, that is, VFKU-NLS1, OPCR code (KRS = 256), which has all 1-coded bits (the OPCR code is mainly used), is assigned to the newly assigned VFCU-NLS there is VFKU-NLS2, and then transmitted through channel I. As a second example, we consider the case when one of the OPKR codes created in the same branch of OPKR as the VFKU-NLS used in AA at the current time is selected as OPKR code that should be used for the newly appointed VFKU-NLS2. As a third example, the case is considered when the RNC RACS of the code to be used for the newly assigned BFC-NLS2 changes to 128.

As described above, when the AA receiving the SIFK-NLS is exchanged with the Node B transmitting on the downlink channels using the closed loop antenna diversity scheme that uses 2 HFCS-NLS, the communication between the AA and the Node B is as follows. AA transmits feedback information to control the gain of the closed loop antenna of the VFK-NLS signal transmitted by nodes B in the active set AA, created when AA enters the MP region, through the IOS field of the VFKU-NLS previously used before AA is located in the region MP, that is, VFKU-NLS1, and AA transmits feedback information only for SIFK-NLS to the node B transmitting the SIFK-NLS signal in the IOS field of the newly used VFKU-NLS, that is, VFKU-NLS2, thus controlling the corresponding koeffi ientami gain antenna for transmitting DL-SIPA. As a result, AA can obtain a sufficient gain when a closed-loop antenna is spaced when a SIFK-NLS signal is received. As described above, VFKU-NLS1 can be used in the transmission of feedback information to control the transmission coefficient of the antenna VFK-NLS. On the other hand, feedback information can also be transmitted to control the transmission coefficient of the VFK-NLS antenna in the IOS field of the newly used VFKU-NLS2.

As it was established above, by separately transmitting feedback information for SIFK-NLS and feedback information for VFK-NLS, feedback information for SIFK-NLS can be obtained by measuring the DPC from node B transmitting SIFK-NLS, measuring the pilot signal field at the VFC -NLS or direct measurement of SIFK-NLS, and feedback information for the IFC can be obtained on the basis of the optimal parameter - antenna gain by summing the signals of the DPC transmitted from the corresponding nodes In the active set AA.

Further, as shown in FIG. 4F, when the node B1, to which the SIFK-NLS is currently connected, is the primary node B, the weights applied to the PAIR circuit are determined depending on the level of received power of the UIC from node B1, s so that all weights a1 and a2 are set to "1". When the node B1 is not the primary node B, the DPC values are weighed with weighting factors a1 and a2 (where a1> a2) in order to increase the reliability of the weighting factors of the pairs used for SIFK-NLS, and then fed to the decision making device 495 regarding the weight PAR The decision making device 495 regarding the PAIR weighting factor creates different weights in different ways that need to be supplied to all cells in the active set according to the circumstances. The operation of the measurement of the PAR channel using AA, which receives SIFK-NLS using the proposed PAR scheme, can be represented as

In equation (1), H _i is the channel matrix (where i denotes the ID number of node B), w is the weight coefficient of the antenna, and a is the weight coefficient for node B _i .

FIG. 5 is a flowchart of a transmission diversity control process shown in FIG. 4A. As shown in FIG. 5, in a state where AA 411 is in communication with node B1 401, that is, where AA 411 is in normal communication not in the MP domain (step 500), AA 411 determines whether the WFC-NLS with SIFK-NLS and SIFK-NLS received from node B1 401 in the PAR mode (step 503). If it is determined that SIFK-NLS and VFK-NLS do not work in PA mode, then AA 411 returns to step 500. However, if SIFK-NLS and VFK-NLS operate in coupled mode, then AA 411 determines whether it is located in the MP region (step 505). If it is determined that AA 411 is not located in the MP region, then AA 411 returns to step 500. However, if it is determined that AA 411 is located in the MP region, then AA 411 determines whether or not to add a VFK-NLS node B2 403, that is, another node B, in addition to the current node B1 401, to the active set (step 507).

If it is determined that the SFC-NLS of node B2 403 is not added to the active set, then AA 411 proceeds to step 513. Otherwise, if it is determined that the SFC-NLS of node B2 403 is added to the active set, then AA 411 determines whether work node No, whose VFK-NLS is added to the active set, in the PAR mode (step 509). If it is determined that the Node B, whose VFK-NLS has been added to the active set, cannot operate in PAIR mode, then AA 411 proceeds to step 513. However, if it is determined that the Node B whose VFK-NLS is added to the active set can operate in the PAR mode, then AA 411 allows the node B, whose VFK-NLS is added to the active set, to use the PVRP or OA mode instead of the PAR mode (step 511). Next, AA 411 determines whether the SIFK-NLS handover has been completed (step 513). If it is determined that the handover has not been performed for the SIFK-NLS, then AA 411 proceeds to step 519. Otherwise, if it is determined that the handoff has been performed for the SIFK-NLS, then AA 411 determines whether the B1 401 node uses the PAIR mode ( step 515).

If it is determined that the Bl 401 node does not use the PAIR mode, then AA proceeds to step 519. However, if it is determined that the Bl 401 node uses the PAIR mode, then AA 411 switches the PAR mode of the Bl 401 node to the STP or OA mode (step 517). After that, AA 411 determines whether the node B2 403 can be used in the PAR mode (step 519). If it is determined that the B2 403 node cannot be used in the PAR mode, then AA 411 returns to step 500.

However, if it is determined that the B2 403 node can be used in the PAR mode, then AA 411 enables the PAR mode for the B2 403 node and then ends the operation (step 521).

FIG. 6 illustrates an AA structure for performing the transmit diversity control process shown in FIG. 4A. As shown in FIG. 6, an input signal AA 411 is supplied through an antenna 701 and then supplied to a downconverter 702. The down-converter 702 down-converts the received signal by mixing it with the composite frequency fc and feeds the down-converted signal to a low-pass filter (LPF) 703. A low-pass filter 703 filters the lower frequencies of the down-converted signal that comes from the down-converter 702 and supplies the filtered main-band signal to an analog-to-digital converter (A / D) 704. The ADC 704 converts an analog the signal of the main frequency band coming from the low-pass filter 703 into a digital signal and delivers the converted digital signal to branch No. 1.

In branch No. 1, the general-purpose processor 705 normally processes the digital signal coming from the ADC 704 in the PAIR mode and the PVRP mode and provides its output to the switch 706. The switch 706 under the control of the transmit diversity mode selection controller 710 (or the diversity mode selection controller 710) when transmitting for VFK-NLS / SIFK-NLS during MP) switches the output signal of the general-purpose processor 705 to the PAR mode processor 707 or the PVRP / OA processor 708, and then the switched signals coming from the PAR mode processor 707 and processor 708 mode PVRP / OA, served in the processor 709 for digital signal processing (DSP). In this case, the transmit diversity mode selection controller 710 operates in accordance with the algorithm shown in FIG. 5. In Fig.6, branch No. 2 and branch No. 3 work in the same way as branch No. 1. DSP 709 processes the digital data for the service required by AA 411, using the resulting signals from the PAR mode processor 707 or the TAP mode / OA processor 708, and transfers the processed data to the upper layer.

FIG. 7 illustrates an AA structure for performing the transmit diversity control process shown in FIG. 4D. As shown in FIG. 7, a radio signal transmitted over the air enters through an antenna 801 and then is supplied to the down converter 802. The downconverter 802 downconverts the received radio signal by multiplying it by a signal with a predetermined composite frequency fc and feeds its output signal to the low-pass filter 803. The low-pass filter 803 filters the low frequencies of the signal coming from the low-frequency converter 802 and delivers the filtered ones low-frequency analog signal in the ADC 804. The ADC 804 converts the analog signal coming from the low-pass filter 803 into a digital signal and supplies the converted digital signal to the first branch "Branch No. 1" and the second I am branching "Branch number 2". In this case, the first branch serves to process the signals received from the node B1 461, while the second branch serves to process the signals received from the node B2 463 (Fig. 4D).

In branch No. 1, the descrambler 805 descrambles the output of the ADC 804 by multiplying by the scrambling code C _{sc, 1} for node B1 461. Block 806 of narrowing the spectrum narrows the spectrum of the output signal of descrambler 805 by multiplying it by the spreading code C _{sp, 1} for node B1 461. The accumulating adder 807 sums the output signal of the spectral narrowing unit 806 and supplies the total signal to a weighting generator 811. A weighting generator 811 calculates a weighting factor w _A = argmax || w ^T h _A || ² to maximize the SINR depending on the signal coming from the accumulating adder 807.

In branch No. 2, the descrambler 808 descrambles the output of the ADC 804 by multiplying it by the scrambling code C _{sc, 2} for node B2 463. The second block 809 of the spectral narrowing produces a narrowing of the output signal of the descrambler 808 by multiplying it by the code C _{sp, 2 of} the spectrum extension for node B2 463. The accumulating adder 810 summarizes the output signal of the second spectral narrowing unit 809 and provides a sum signal to the adder 812. The adder 812 sums the output signal of the accumulating adder 807 with the output signal of the accumulating adder 810 and provides its output s drove into the generator 813 weights. Weighting generator 813 calculates a weighting factor w _AB = argmax || w ^T h _AB || ² to maximize the SINR depending on the signal coming from the adder 812.

FIG. 8 illustrates the structure of a node B for performing the transmit diversity control process shown in FIG. 4D. As shown in FIG. 8, radio signals transmitted from AA 471 through a first antenna (ANT1) 859 and a second antenna (ANT2) 860 are transmitted to a demultiplexer (DEMUX) 852. The demultiplexer 852 detects feedback information (IOS) from the signals WFCI of the radio signals received through the first and second antennas 859 and 860, and provides the detected feedback information to the generator 851 weight factors. A weighting generator 851 produces complex, floating point weights w = | w | exp (j), that is, w ₁₁ , w ₁₂ , w ₂₁ and w ₂₂ , by combining the input bits as required based on feedback information from the demultiplexer 852, and supplies the generated weights w ₁₁ , w ₁₂ , w ₂₁ and w _22, respectively, to the multipliers 855, 856, 863 and 864.

Meanwhile, the multiplexer (MUX) 853 multiplexes the CFCI signal and the CFCI signal into a dedicated physical channel signal (DPCH) and supplies the CFC signal to the multiplier 854. The multiplier 854 multiplies the CFC signal from the multiplexer 853 by an expanding and scrambling code for node B1 461 and provides its output signal to the multiplier 855 and the multiplier 856.

The multiplier 855 multiplies the weight coefficient w ₁₁ from the weight generator 851 by the output of the multiplier 854 and feeds its output signal to the adder 857. The multiplier 85 multiplies the weight coefficient w ₁₂ from the weight generator 851 by the output signal multiplier 854 and provides its output signal to the adder 858.

In addition, the multiplier 862 multiplies the CIFK-NLS signal by the spreading spectrum and the scrambling code for the node B1 461 and feeds its output signal to the multiplier 863 and the multiplier 864. The multiplier 863 multiplies the weight coefficient w ₂₁ from the weight generator 851 by the output signal of the multiplier 862 and feeds its output signal to the adder 857. The multiplier 864 multiplies the weight coefficient w ₂₂ from the weight generator 851 by the output signal of the multiplier 862 and provides its output signal to the adder 858.

The adder 857 adds the output of the multiplier 855, the output of the multiplier 863 and the first signal of the common pilot channel (OPC ₁ (CPICH ₁ )) and transmits the total signal through the first antenna 859. The adder 858 adds the output of the multiplier 856, the output multiplier 864 and the second common pilot channel signal (DIC ₂ (CPICH _2)), and transmits the summed signal through the second antenna 860. Accordingly, it is possible to apply different weights to the DL-DPCH signal and the signal SIPA based on the DL-yn feedback deformations of UL-DPCCH signal received from the UE 471.

Meanwhile, in FIGS. 4A-4F, if the mode switching is performed using information regarding the fast cell selection (FCS), then the advanced SIFK-NLS (P-SIFK-NLS) supporting the NBC will work as follows. In this case, the BVI determines from which node B AA it is necessary to receive data, and provides node B with relevant information. Therefore, if AA determines the node B that will transmit the P-SIFK-NLS based on the BVI, then AA creates the weights necessary for the serving cell of the S-SIFK-NLS, and then transfers the created weights to the serving cell of the S-SIFK-NLS using iOS. That is, in the field of MP, AA pre-recognizes the arrival time of the R-SIFK by receiving the ICFT bits, including information regarding the initial moment of transmission, from the serving cell of the P-SIFK-NLS and, thus, switches to the above modes, i.e., modes, shown in figa-4F. In other words, the target node B, which calculates the weighting coefficients, dynamically changes according to the node B, determined using AA.

For example, when the R-SIFK-NLS data of two or more frames is sequentially received from the same Node B using information from the BVN, AA can transmit information about the CM bits (state machine (FSM), type of shift register) IOS pair, starting from the next bit relative to the position of the previous bit, and not from the original bit. If AA has changed the cell or could not receive the immediately preceding frame, AA retransmits the CM bits, starting with the original bit. However, when AA simply transmits the information about the KM bit in the same format as in mode No. 1 of the ODPP (General Packet Transfer Protocol (GPP)) (or UMTS (Universal Mobile Telecommunication System (UMTS)) W-CDMA), you can continuously transmit KM bits from the IOS regardless of whether the cell is determined based on the BVI. In addition, when the R-SIFK-NLS and normal SIFK-NLS use the information transmitted by the R-SIFK-NLS and SIFK-NLS in the MP region, the R-SIFK-NLS and SIFK-NLS should operate in accordance with the number of intervals intended for transfer of IOS required by SAR.

FIG. 9 illustrates a SIFK-NLS / P-SIFK-NLS transmission procedure based on a transmission timing according to a seventh embodiment of the present invention. As shown in FIG. 9, in the MP region between the nodes B supporting the PA mode, AA operates in the normal mode of the VFC coupler (step 911). When AA enters the MP region, AA determines whether SIFK-NLS / R-SIFK-NLS from node B is received in the WFC pair mode (step 913). If it is determined that the SIFK-NLS / R-SIFK-NLS is not received from the Node B, then AA performs the general mode of the HFC pair (step 911). However, if it is determined that SIFK-NLS / P-SIFK-NLS is received from node B, then AA re-selects node B having good channel conditions depending on the BWI, thereby increasing reliability and decreasing determination time. That is, in the MP domain, AA repeatedly selects a node B having the best channel conditions among the plurality of nodes B from which signals are received using a PC, thus selecting a node B having the best channel conditions. After receiving the SIFK-NLS / P-SIFK-NLS AA, it determines whether data has been received from the same Node B based on a time-sequence (step 915). If it is determined that the data has been received from the same Node B based on the time sequence, AA maintains the KM IOS PAR index in mode No. 1 using 2 bits and initializes the KM IOS PAR index in “0” in mode No. 2 using 4 bits (step 917). If data is received from the same Node B based on the “time sequence”, then AA applies the new data output based on the previous result. However, if data is not received from the same Node B or received with a time delay, AA applies a new value based on a predefined offset or result that was previously applied to another Node B, and then performs the addition of SIFK-NLS / P-SIFK- NLS, creating and feedback or switching the SIFK-NLS / R-SIFK-NLS mode between the SAR mode and the PVRP / OA mode (step 919). After that, the AA determines whether the transmission / reception of SIFK-NLS / R-SIFK-NLS is completed (step 921). If it is determined that the transmission / reception of SIFK-NLS / R-SIFK-NLS is completed, then AA changes its mode of operation from PVRP or OA mode to the mode of VFK VAR (step 911). Otherwise, if it is determined that the SIFK-NLS / R-SIFK-NLS transmission / reception is not completed, then AA again determines whether the SIFK-NLS / R-SIFK-NLS is received from the Node B (step 913).

As described above, in the field of MP AA can control the transmitting antenna array for SIFK-NLS, making it possible to use the necessary weights for the diversity of the transmitting antennas. Moreover, in the field of MP, AA can control the transmit antenna array for R-SIFK-NLS / SIFK-NLS, making it possible to use the required weights of the transmit antennas. In addition, in the field of MP AA can separately use the weight coefficient of the transmitting antenna for SIFK-NLS and the weight of the transmitting antenna for VFK-NLS, thus solving the problem caused by the known MP scheme, namely that the applied weights are different from the required weights transmitting antennas as a result of using the same weighting coefficients of transmitting antennas for SIFK-NLS and VFK-NLS.

Although the present invention has been shown and described with reference to specific preferred embodiments, it will be apparent to those skilled in the art that various changes in form and content can be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (2)

1. A device for controlling the diversity of data transmitted from node B to user equipment (AA), which is in the process of soft handoff between the first node B, which transmits a shared channel signal downlink and a dedicated channel signal, and the second node B, which transmits a dedicated channel signal containing a first block for narrowing the spectrum of the signal received from the first node B using the first spreading code and outputting the first signal with a narrowed spectrum, the second block for narrowing the spectrum of the signal received from the second node B, using the second spreading code and output the second signal with a narrowed spectrum, a transmit antenna array weighting coefficient (PAR) generator for generating a PAR weighting factor for use in a downlink shared channel and a dedicated channel by receiving the first signal with a narrowed spectrum and the second signal with a narrowed spectrum, moreover, the weight coefficient of the PAR is determined by the first node B to a greater extent than the second node B, and a transmitter for generating feedback information including a weight factor of the PAR and transmitting the generated feedback information to the first node B and the second node B. 2. A method for controlling the diversity of data transmitted from node B to user equipment (AA), which is in the process of soft handoff between the first node B, which transmits a shared channel signal downlink and a dedicated channel signal, and the second node B, which transmits a dedicated channel signal, comprising the steps of: narrowing the spectrum of the signal received from the first node B using the first spreading code and outputting the first signal with a narrowed spectrum, narrowing the spectrum of the signal received from the second of the second node B, with the help of the second spreading code and the second signal with a narrowed spectrum is output, a weighting factor is generated for the PAR for use in the shared downlink channel and the dedicated channel by receiving the first signal with the narrowed spectrum and the second signal with the narrowed spectrum, and the PAR coefficient is determined by the first node B to a greater extent than the second node B, and feedback information including the weight coefficient of the PAR is generated, and the generated feedback information is transmitted tie in the first Node B and a second Node B.

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