KR100357265B1 - A method for power control of tfci field in a mobile communication system of 3gpp standard - Google Patents

Abstract

The present invention performs separate power control on a transport format combination identifier (TFCI) field indicating a transport format of a downlink shared channel (DSCH) in an IMT-2000 system (3GPP system) that promotes standardization in 3GPP. The present invention relates to a transmission power control method of a TFCI field for a DSCH in a mobile communication system to improve the performance of a DSCH.

The present invention performs transmit power control on the TFCI bit in proportion to transmit power control on the DSCH. In the present invention, when two bits are allocated as the TFCI bit for the DSCH and the TFCI field for the DCH in the TFCI field, the entire TFCI field is adjusted to the transmission power level of the TFCI field indicating the transmission format of the downlink shared channel (DSCH). . Alternatively, when the mobile station is in soft handover, the power of the TFCI field is controlled by assigning different power offsets to the base station and the base station other than the main base station. Alternatively, when the mobile station is in soft handover, power corresponding to the base station other than the primary base station is allocated as the power of the TFCI field regardless of the SSDT.

Description

FIELD OF POWER CONTROL OF TFCI FIELD IN A MOBILE COMMUNICATION SYSTEM OF 3GPP STANDARD}

The present invention provides separate power control for a transport format combination identifier (TFCI) field indicating a transport format of a downlink shared channel (DSCH) in an IMT-2000 system (hereinafter, referred to as a 3GPP system) that promotes standardization in 3GPP. The present invention relates to a transmission power control method of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system so as to improve the performance of the DSCH.

In the present invention, in performing transmission power control on a TFCI bit indicating a transmission format of a DSCH, transmission power control of a TFCI field is performed to be proportional to transmission power control on a DSCH.

More specifically, the present invention, in performing the power control of the TFCI bit for the DSCH in the 3GPP system, by assigning a different power control scheme to the TFCI bit according to the mode selected by the user equipment (UE) The mobile station measures the power from each base station to set the base station with the largest power as the primary base station, and when the base station to which the DSCH is transmitted is selected as the primary base station, it transmits to a TPC command such as a DCH. Power control method of a TFCI field for a DSCH channel during handover of a 3GPP system, characterized in that power control is performed by adjusting a transmission power and transmitting a constant power when the base station to which the DSCH is transmitted is not the main base station. It is about.

In addition, the present invention, in performing the power control of the TFCI field for the DSCH in the 3GPP system, by assigning a scheme in which the DSCH and the DCH to control the power by different TPC commands, respectively, except for the TFCI field for the DSCH and the DSCH The present invention relates to a power control method of a TFCI field for a DSCH channel during handover of a 3GPP system, characterized in that the power is controlled by changing a power by a different TPC command for the TFCI field.

The 3GPP system has a downlink shared channel (DSCH) as a channel for transmitting a data type. 1 shows a configuration of a DSCH channel. The DSCH channel consists of a radio frame of 10ms, which can be used by different users in each frame, and codes generated by codes assigned by multiple users as mother codes for the DSCH channel. It can be shared by multiple users. That is, the DSCH is a code multiplexing and time multiplexing channel shared by several users.

Although the DSCH channel is shared by multiple users, a code with a constant data rate at a moment is used by only one user.

Thus, while the DSCH is occupied by each user, power control is performed by each user. In power control, a mobile station (UE) may transmit a power control command by measuring the power of a dedicated channel (DCH). The DSCH adjusts power transmitted according to this power control command (TPC).

2 shows the channel structure of the DCH. However, the DCH performs soft handover, whereas the DSCH channel does not perform soft handover. Therefore, when the DCH is in soft handover and the DSCH is transmitted from only one base station, different power control is required for both.

That is, a TPC is generated by summing power from several base stations, but since the DSCH channel is transmitted from one base station, the TPC command does not keep up with the change in power experienced by the DSCH. In this case, power control of the DSCH channel should be different.

There are two methods of such power control as follows.

The first method operates in two modes, in which the mobile station (UE) measures the power from each base station, selects the base station having the largest received power, and sets it as the main base station. In the case where the base station to which the DSCH is currently transmitted is the main base station, the base station transmits power at a predetermined level higher than the reference power, and changes the power according to the TPC command generated by the DCH. If the base station to which the DSCH is transmitted is not the main base station, the base station transmits the power at a constant high power.

The second method is a method in which a mobile station (UE) generates and transmits a TPC and a DSCH, respectively, for a DCH. For this purpose, the mobile station (UE) needs to measure not only the DCH power but also the power of the DSCH channel. The power control of the DCH is connected like a DCH. The configuration of the DSCH channel is shown in FIG. 1 and the configuration of a downlink DCH channel is shown in FIG.

Referring to FIG. 1, the DSCH channel is composed of radio frames having a frame period (T _f ) = 10 ms, has a structure of 15 slots (Slot # 0 to Slot # 14), and any one slot T _slot = 2560. chips, consisting of N _data bits of 20 * 2 ^k bits (k = 0..6).

2, the downlink DCH channel is composed of a radio frame having a frame period (T _f ) = 10 ms, has a structure of 15 slots (Slot # 0 to Slot # 14), and any one slot T _slot. = 2560 chips, 20 * 2 ^k bits (k = 0..7), with DPDCH (Dedicated Physical Data CHannel) and DPCCH (Dedicated Physical Control CHannel) . The first DPDCH carries N _data1 bits of data (Data1), and the next DPCCH carries TPC command N _TPC bits and TFCI N _TFCI bits, and the next DPDCH carries N _data2 bits of data (Data2). In the end, the DPCCH carries a _pilot of N _pilot bits.

Here, the TFCI bit contains information about the channel currently being transmitted. For example, information about the amount of data and the coding method transmitted in the radio frame to be transmitted is transmitted. When data of a user is simultaneously transmitted through the DCH and the DSCH, the information on the DCH and the information on the DSCH should be simultaneously transmitted. The TFCI bits transmitted per slot are divided into two, half are used for the DCH, and half are used for the DSCH.

The TPC is a TPC for power control of the uplink channel. This is used to change the power of the uplink (reverse direction). The pilot is used to measure the power of the channel.

Meanwhile, a process of downlink (forward) power control is performed as follows.

First, the UE estimates the SIR (Signal to Interference Ratio) of the DCH, compares the measured SIR _est with the target SIR _target, and the measured SIR _est is larger than the target SIR _target (SIR _est SIR _target ). Transmits a TPC command of '0' and, if the measured SIR _est is smaller than the target SIR _target (SIR _est <SIR _target ), transmits a TPC command of '1'.

The base station then uses the transmitted TPC to adjust the power of the DCH as follows.

P (k) = P (k-1) + P _TPC (k). That is, the current power P (k) adds or subtracts the adjustment P _TPC (k) to the previous power P (k-1). When TPC _est (k) = 1, P _TPC (k) = + ΔTPC, TPC _est ( k) = 0 where P _TPC (k) = − ΔTPC. That is, when the measured SIR _est is smaller than the target SIR _target , the power of the DCH is increased by + ΔTPC, and when the measured SIR _est is larger than the target SIR _target , the power of the DCH is reduced by + ΔTPC.

Here, the TFCI field of the DPCCH has the power of P _TFCI (k) = P (k) + PO3 (where PO3 is the power offset of the DPDCH and TFCI field).

However, in the case of power control of the conventional DSCH as described above, the TFCI bit is not considered. That is, since the TFCI bit transmits important information such as the number of data bits of the currently transmitted frame, the coding method, and the like, when the TFCI is incorrectly received, the data of the radio frame cannot be detected correctly. It is difficult to expect the performance improvement of the DSCH since the current consideration is for the power control of the DSCH, not the power control of the TFCI for the DSCH.

That is, when the TFCI bit is not properly received, since the information on the spreading factor or data amount of the DSCH is not properly transmitted, the information of the frame corresponding to the TFCI is not correctly transmitted.

On the other hand, the TPC during soft handover is generated by the combined power of the DPCCH. The TFCI bits for the DSCH are received at different powers because only one base station transmits the bits. Thus, even if the TFCI bit is received with less power than the reference power, according to the power control method described above, the transmission power may be lowered by the TPC. That is, there is a problem in that the quality of the TFCI for the DSCH cannot be guaranteed.

In addition, when the power control of the conventional DSCH channel using a separate TPC, there is a disadvantage that the TPC cannot be generated because the SIR of the DSCH cannot be measured when the DSCH is not delivered.

The present invention provides a transmission power of a transport format combination identifier (TFCI) included in a downlink dedicated channel (DCH) so that information loss is minimal even when the DCH associated with the downlink shared channel (DSCH) is in a soft handover situation. Suggest a way to control it.

According to the present invention, in performing transmission power control on a TFCI bit indicating a transmission format of a DSCH, a power control method of a TFCI field for a DSCH channel for controlling transmission power for a TFCI bit to be proportional to transmission power control for a DSCH. Suggest.

In addition, according to the present invention, a power control method of a TFCI field for a DSCH channel during handover of a 3GPP system to improve the reception quality of the TFCI bit for the DSCH by performing power control separate from the TFCI bit with the DCH is proposed. .

In the present invention, by controlling the power of the TFCI bit according to the TPC for power control of the DSCH, the DSCH channel at the time of handover of the 3GPP system to receive the power of the TFCI and generate the TPC even when the DSCH channel is not transmitted. We propose a power control method for the TFCI field.

1 illustrates a configuration of a DSCH channel

2 illustrates a configuration of a DCH channel

3 illustrates a field structure of DPDCH and DPCCH

According to the present invention, the transmission power control of the TFCI field, which is classified by dividing the TFCI field indicating the transmission format of the downlink shared channel (DSCH) from other fields in the dedicated physical channel (DPCH), is applied to the power control of the downlink shared channel (DSCH). A method for controlling transmission power of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system, characterized in that it is controlled proportionally, and is applied to a case where a user (mobile station) is in a handover situation or not. It is a possible power control method, and in particular, a transmission power control method of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system which is effective during handover.

In the present invention, the power control of the TFCI field, the step of selecting a primary base station for each base station in the mobile station, adjusting the transmission power by the ΔTPC, such as DCH when the base station to which the DSCH is transmitted is a primary base station, In the mobile communication system, when the base station to which the DSCH is transmitted is not the main base station, the base station transmits with a constant power. The TFCI field transmit power control method for the downlink shared channel (DSCH) in the mobile communication system.

In the present invention, the power control of the TFCI field, TPC for the TFCI field for the DSCH and TPC of the remaining portion except for the TFCI field for the DSCH, respectively, characterized in that the power is changed by each TPC A transmission power control method of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system.

In addition, the present invention is characterized in that in generating the TPC for the TFCI field, by measuring the power of the TFCI to predict the SIR and accordingly generate the TPC.

In another aspect, the present invention is characterized in that when the TFCI bit for the DSCH and the TFCI bit for the DCH in the TFCI field is transmitted as one symbol, power control the TFCI field according to the TPC for power control of the TFCI bit for the DSCH do.

In addition, the power control method of the TFCI field for the DSCH channel that is effective in the handover of the 3GPP system of the present invention, determining whether the DCH associated with the DSCH is in a soft handover state, each base station in the mobile station Selecting a primary base station for the base station, determining whether the base station transmitting the DSCH is the primary base station or not the primary base station, and when the mobile station is in soft handover, the primary base station and the non-main base station Assigning different power offsets to each other to control the power of the TFCI field; The power control method of the TFCI field for the DSCH channel during handover of the 3GPP system, characterized in that comprises a.

In addition, the power control method of the TFCI field for the DSCH channel in the handover of the 3GPP system of the present invention, regardless of the Site Selection Diversity Transmit (SSDT) when the mobile station is in soft handover, The power corresponding to the base station other than the main base station is characterized by allocating power of the TFCI field.

In addition, the power control method of the TFCI field for the DSCH channel of the 3GPP system of the present invention is characterized by allocating the same power as in the soft handover even when the mobile station is not in the soft handover.

In addition, the power control method of the TFCI field for the DSCH channel in the handover of the 3GPP system of the present invention, when the TFCI bit for the DSCH and the TFCI bit for the DCH in the TFCI field is transmitted in one symbol, for the DCH The TFCI bit and the TFCI bit for the DSCH are controlled by different power.

A method of controlling transmission power of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system according to the present invention will be described.

In particular, the present invention describes a power control method of the TFCI field for the DSCH channel of the 3GPP system that is effective during soft handover as an embodiment.

Typical downlink power control adjusts the power of the DPCCH and DPDCH simultaneously.

The power of each of the DPCCH and the DPDCH is adjusted by the same amount, and the relative ratio of the DPDCH and the DPCCH does not change. However, if the DCH associated with the DSCH is in soft handover situation, a different approach is required. That is, in order to maintain the reception quality of the TFCI bit, the TFCI bit for the DSCH is subjected to different power control. Power control of the TFCI bit for the DSCH may be used the same method as the above-described DSCH power control.

In the present invention, two methods are proposed as a power control method of the TFCI field for the DSCH channel which is effective in the handover of the 3GPP system.

First, a method of allocating power in a different manner depending on the mode in which the TFCI bit is selected by the UE.

2, power adjustment of the DPCCH and DPDCH in the remaining portions except for the TFCI field is performed by the conventional method. However, different power control is applied to the TFCI field depending on the mode selected by the mobile station (UE).

First, the mobile station UE measures the power coming from each base station, and sets the base station with the largest power among them as the main base station. If the base station to which the DSCH is transmitted is selected as the primary base station, power control of the TFCI field for the DSCH is performed like the other fields of the DPCCH, and if the base station to which the DSCH is transmitted is not the primary base station, the base station transmits with constant power.

That is, the power P _TFCI (k) of the _{TFCI transmits} P _TFCI (k) = P (k) + PO 3 + Pp when the main base station is used, and P _TFCI (k) = Pnp when the main base station is not. Therefore, the case where the primary base station is not compared with the primary base station is transmitted with greater power.

Here, Pp is a parameter for transmitting at a higher power than the reference TFCI power, and Pnp is a parameter for constantly transmitting at a power when the mobile station UE is at the cell boundary when the base station is not the main base station.

However, in setting the power of the TFCI as described above, the base station transmitting the DSCH is always set to the base station instead of the main base station without allocating power according to whether the base station to which the DSCH is transmitted is the main base station or not. Therefore, a technique of transmitting with a constant power may be applied.

In this case, power is allocated by P _TFCI (k) = Pnp regardless of SSDT operation.

Alternatively, in setting the TFCI power of the base station transmitting the DSCH, power may be allocated as follows depending on whether or not the primary base station is used.

That is, the power P _TFCI (k) of _TFCI is P _TFCI (k) = P (k) + Pp when the base station transmitting the DSCH is the main base station, and P _TFCI (k when the base station transmitting the DSCH is not the main base station. ) = P (k) + Pnp.

Here, Pp is a power offset when the base station transmitting the DSCH is the main base station, and Pnp is a power offset when the base station transmitting the DSCH is not the main base station. If the base station is not the main base station to set a high Pnp value to transmit at the power considering the cell boundary, or when setting a Pnp value above the power that can be allocated by TFCI TFCI is transmitted at full power.

The second method of the power control method of the TFCI field for the DSCH channel of the 3GPP system of the present invention is a case where the DSCH and the DCH are controlled by different TPCs.

That is, as a method of changing the power by a TPC different from the remaining portion except for the TFCI field for the DSCH and the TFCI field for the DSCH, the mobile station (UE) is configured for TPC1, DSCH, and TFCI for the DCH except for the TFCI field. Generate TPC2.

For this purpose, the UE measures two powers. One is for power control of the DCH, and the other is for power control of the DSCH and TFCI bits for the DSCH. SIR is measured using a pilot of the DPCCH to make a TPC for the DCH.

On the other hand, the TFCI bit and the DSCH channel are used for the DSCH channel. When using the DSCH channel, it is easy to measure SIR because it is transmitted continuously with strong power. However, there is a frame in which the DSCH is not transmitted. This prevents SIR measurements in this section. The TFCI bit occupies only a portion in one slot but is transmitted continuously, so the SIR can be measured in every frame. DCH excluding the TFCI bit is adjusted in power like P1, and the DSCH and TFCI bits are adjusted in P2.

That is, P1 (k) = P1 (k-1) + P _TPC1 (k). That is, the power P1 (k) of the DCH present except the TFCI bits for subtraction to jojeongbun P _TPC1 (k) by the TPC1 to the previous power P1 (k-1), TPC1 est (k) = 1 when P _TPC1 (k ) = + ΔTPC, P _TPC1 (k) = -ΔTPC when TPC1 _est (k) = 0. That is, if the measured SIR _est is smaller than the target SIR _target , the power of DCH excluding TFCI is increased by + ΔTPC. If the measured SIR _est is larger than the target SIR _target , the power of DCH excluding TFCI is reduced by + ΔTPC. It is to let.

On the other hand, P2 (k) = P2 (k-1) + P _TPC2 (k). That is, the current P2 (k) of the DSCH and TFCI bits is added to or subtracted the adjustment P _TPC2 (k) by TPC2 to the previous power P2 (k-1), which is P _TPC2 (k) when TPC2 _est (k) = 1. P _TPC2 (k) = -ΔTPC when TPC2 _est (k) = 0. That is, when the measured SIR _est is smaller than the target SIR _target , the power of the DSCH and TFCI bits is increased by + ΔTPC. When the measured SIR _est is larger than the target SIR _target , the power of the DSCH and TFCI is reduced by + ΔTPC. will be.

Where P _TFCI (k) = P2 (k) + PO3 (where PO3 is the power offset of the DPDCH and TFCI fields).

Meanwhile, in the case of a base station transmitting a DSCH, both the first method and the second method of the present invention may be applied to both the user at the time of handover or otherwise.

That is, in the power control of the TFCI field for the base station transmitting the DSCH, power of a different method depending on the mode in which the user (mobile station) selects the TFCI bit regardless of whether the user (mobile station) is in handover or not. Can be used, and a method of allowing the DSCH and the DCH to be controlled by different TPCs can be used.

In allocating the power of the TFCI bit for the DSCH, a method of allocating power such as TFCI for the DCH and a method of allocating different power may be used. That is, the power of the TFCI bit for the DSCH is allocated to the same power as the TFCI for the DCH or different powers are allocated.

The DCH is transmitted in a QPSK signal.

On the other hand, when power control of the TFCI bit for the DSCH and the TFCI for the DCH differently, a real signal and an imaginary signal of one symbol may have different powers. That is, such a case occurs when two bits are allocated as the TFCI field as shown in FIG. To prevent this, adjust the entire TFCI field to the power of P2.

That is, the TFCI bit includes a TFCI bit for the DCH and a TFCI bit for the DSCH, and a bit for the DCH and the DSCH is transmitted in one symbol. In this case, a TFCI field including the TFCI bits is used as a TFCI for the DSCH. Power control is performed according to the TPC for power control of bits.

The present invention proposes a power control scheme of TFCI, which can reduce signal loss even when the DCH associated with the DSCH is in a soft handover situation. The power quality of the TFCI bit for the DSCH can be improved by performing power control separate from the DCH. If the TFCI bit is not properly received, since information on the spreading factor or data amount of the DSCH is not properly transmitted, information of the frame corresponding to the TFCI is not correctly transmitted. However, according to the present invention, since such a concern can be solved, the performance of the DSCH can be improved.

In addition, when the power control of the conventional DSCH channel using a separate TPC, there is a disadvantage that the TPC cannot be generated because the SIR of the DSCH cannot be measured when the DSCH is not delivered. However, in the present invention, power control of the TFCI bit according to the TPC for power control of the DSCH may generate the TPC by receiving the power of the TFCI even when the DSCH channel is not transmitted.

Claims (4)

Distinguishing a TFCI field indicating a transmission format of a downlink shared channel (DSCH) used by a plurality of users from another field in a downlink dedicated channel (DCH), and controlling transmission power of the divided TFCI field in the downlink shared channel Controlling to be proportional to power control of the DSCH; A transmission power control method of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system characterized by performing a transmission power control. The transmission power level of the TFCI field according to claim 1, wherein when two bits are allocated as the TFCI bit for the DSCH and the TFCI field for the DCH in the TFCI field, the TFCI field indicates the transmission format of the downlink shared channel (DSCH). Transmitting power of a TFCI field for a downlink shared channel (DSCH) in a mobile communication system. 2. The method of claim 1, further comprising: determining whether the DCH associated with the DSCH is in soft handover state, selecting a primary base station for each base station in the mobile station, wherein the base station transmitting the DSCH is the primary base station among the base stations; Or determining whether it is a primary base station, and if the mobile station is in soft handover, allocating different power offsets for the primary base station and a base station other than the primary base station to control the power of the TFCI field; The transmission power control method of the TFCI field for the downlink shared channel (DSCH) in a mobile communication system comprising a. The downlink shared channel (DSCH) in the mobile communication system according to claim 3, wherein when the mobile station is in soft handover, power corresponding to the base station other than the primary base station is allocated as the power of the TFCI field regardless of the SSDT. Transmission power control method of the TFCI field.