JP5964331B2 - Terminal and power control method for executing random access in the terminal - Google Patents

Description

  The present invention relates to a terminal and a power control method for performing random access in the terminal, and more particularly, to a power control method and apparatus when a terminal performs random access in a mobile communication system (Distributed Antenna System) to which a distributed antenna is applied.

  FIG. 1 is a diagram illustrating a structure of a mobile communication system in which a centralized antenna according to the prior art is arranged. In other words, this indicates that a transmission / reception antenna is arranged in the center of each cell in a mobile communication system composed of three cells. The mobile communication system shown in FIG. 1 has a form of CAS (Central Antenna System) in which the antenna of each cell is arranged at the center of the cell. In the case of CAS, even if a plurality of antennas are arranged for each cell, these antennas are arranged at the center of the cell and are operated so as to communicate with the service area of the cell.

  Referring to FIG. 1, the first cell 100 among the first cell 100, the second cell 110, and the third cell 120 includes a central antenna 130 and a first terminal (UE: User Equipment or MS (Mobile) located in the center. Station)) 140 and the second terminal 150 exist. The central antenna 130 provides a mobile communication service to the two terminals 140 and 150 located in the first cell 100. The first terminal 140 that provides the mobile communication service using the central antenna 130 is relatively far from the central antenna 130 compared to the second terminal 150. Accordingly, the data transmission rate that can be supported by the first terminal 150 is relatively lower than that of the second terminal 150.

  When the antenna of each cell is arranged and operated in a CAS form in the mobile communication system as shown in FIG. 1, a reference signal (reference signal (RS) or pilot) is transmitted to measure the downlink channel state for each cell. To do. Therefore, in the case of 3GPP LTE-A (Long Term Evolution Advanced) system, the terminal measures the channel state between the base station and the terminal by using CSI-RS (Channel Status Information Signal) transmitted by the base station. .

  FIG. 2 is a diagram illustrating a position of a CSI-RS transmitted from a base station to a terminal in an LTE-A system according to the prior art.

In FIG. 2, the horizontal axis represents the time domain, and the vertical axis represents the frequency domain. The minimum transmission unit in the time domain is an OFDMA symbol, and N _sym ^DL OFDM symbols are collected to form one slot 222, 223. Two slots gather to form one subframe 224. The minimum transmission unit in the frequency domain is a subcarrier, and the entire system transmission band is composed of _NBW subcarriers in total. N _BW has a value in proportion to the system transmission band. The basic unit of resources in the time-frequency domain is a resource element (RE), which can be defined as an OFDM symbol index and a subcarrier index. Resource blocks (RBs) _{220 and 221} are defined as N _symbol ^DL consecutive OFDM symbols in the time domain and N _sc ^RB consecutive subcarriers in the frequency domain. Therefore, one RB is composed of N _sym ^DL xN _sc ^RB REs. Generally, the minimum transmission unit of data or control information is an RB unit.

  The downlink control channel is transmitted within the first 3 OFDM symbols of the subframe. A PDSCH (Physical Downlink Shared Channel), which is a downlink physical data channel, is transmitted during the remaining subframe period in which the downlink control channel is not transmitted. DM-RS (Demodulation Reference Signal) is a reference signal that is referred to when the terminal demodulates the PDSCH.

  It was devised so that signals for two CSI-RS antenna ports can be transmitted for each position at positions 200 to 219 in FIG. That is, the base station transmits signals for two CSI-RS antenna ports for downlink measurement to a terminal at one position such as reference numeral 200. Antenna port is a logical concept, and CSI-RS is defined for each antenna port, and is operated so as to measure the channel state for each antenna port. If the same CSI-RS is transmitted from a plurality of physical antennas, the terminal cannot distinguish each physical antenna and recognizes it as one antenna port.

  As shown in FIG. 2, in the case of a mobile communication system including a plurality of cells, a CSI-RS can be transmitted by assigning a separate location for each cell. As an example, in the case of the cell 100 shown in FIG. 1, the CSI-RS can be transmitted at the position 200, and in the case of the cell 110, the CSI-RS can be transmitted at the position 205. In the case of the cell 120, the CSI-RS can be transmitted at the position 210. The allocation of time and frequency resources for CSI-RS transmission at different positions for each cell is to prevent CSI-RS of different cells from causing mutual interference. However, as shown in FIG. 1, in the case of CAS, the transmission / reception antennas of each base station are centrally arranged at the center of the cell, thereby supporting a high data transmission rate for terminals far from the center of the cell. There are limits to this.

  FIG. 3 is a diagram showing an example of a system configuration in which CAS and DAS (Distributed Antenna System) are built together in a mobile communication system according to the prior art. More specifically, FIG. 3 shows that in a mobile communication system composed of three cells, a transmitting / receiving antenna is arranged in the center for each cell, and distributed antennas are arranged in different positions in the cell. It is.

  Referring to FIG. 3, the first cell 300 among the first cell 300, the second cell 310, and the third cell 320 includes a central antenna 330 and a first terminal (UE: User Equipment or MS (Mobile) located in the center. Station)) 340, the second terminal 350, the first distributed antenna 360, the second distributed antenna 370, the third distributed antenna 380, and the fourth distributed antenna 390. The central antenna 330 and the plurality of distributed antennas 360, 370, 380, 390 are all connected together and are controlled by the central controller.

  The central antenna 330 provides mobile communication services to all terminals located in the first cell 300. However, the first terminal 340 that provides the mobile communication service using the central antenna 330 is relatively far from the central antenna 330 compared to the second terminal 350. Accordingly, the data transmission rate that can be supported by the first terminal 340 through the central antenna 330 is relatively low.

  As the transmission path of a signal to be normally transmitted becomes longer, the signal reception quality deteriorates. Therefore, by arranging a plurality of base station distributed antennas in a cell, selecting an optimal base station distributed antenna according to the location of the terminal, and providing mobile communication services, the data transmission rate can be improved. . For example, the first terminal 340 communicates with the fourth distributed antenna 390 with the best channel environment, and the second terminal 350 communicates with the first distributed antenna 360 with the best channel environment, thereby relatively high speed. Data services can be provided.

  In this case, the central antenna 330 is responsible for supporting mobility between general mobile communication services other than the high-speed data service and the cell of the terminal. Further, the central antenna 330 and the respective distributed antennas 360, 370, 380, and 390 can be configured by a plurality of antennas.

  FIG. 4 is a diagram showing a system configuration in which central antennas according to the prior art are distributed in various regions in a cell.

  Referring to FIG. 4, a first central antenna 430, a second central antenna 431, a third central antenna 432, and a fourth central antenna are included in the first cell 400 among the first cell 400, the second cell 410, and the third cell 420. Assume that there are 433, a fifth central antenna 434, a first terminal 440, a second terminal 450, a first distributed antenna 460, a second distributed antenna 470, a third distributed antenna 480, and a fourth distributed antenna 490. The central antennas 430, 431, 432, 433, and 434 shown in FIG. 4 are responsible for supporting mobility between general mobile communication services other than high-speed data services and terminals, and distributed antennas are Serves to provide high-speed mobile communication services.

  The logical concepts C-port (Central antenna port) and D-port (Distributed antenna port) are defined below, and are not limited to the physical configuration of the central antenna and the distributed antenna shown in FIG. 3 or FIG. So that it can be logically divided.

  The C-port defines CSI-RS (Channel Status Reference Signal) for supporting CAS for each antenna port, and the terminal can measure the channel state for each antenna port of the C-port. CSI-RS transmitted through C-port covers the entire area of the cell within the same cell. D-port defines CSI-RS for supporting DAS for each antenna port, and the terminal can measure the channel state for each antenna port of D-port. CSI-RS transmitted through D-port covers a partial area in the cell. If the same CSI-RS is transmitted from a plurality of physical antennas, each physical antenna cannot be distinguished by the terminal regardless of the geographical location. It will be recognized as one antenna port.

  For example, if the third distributed antenna 380 and the fourth distributed antenna 390 that are geographically separated in the system structure as shown in FIG. 3 transmit different patterns of CSI-RS # 1 and CSI-RS # 2, respectively, the terminal From CSI-RS # 1 and CSI-RS # 2, the channel state between each distributed antenna and the terminal can be measured. In this case, the third distributed antenna 380 is referred to as D-port # 1, and the fourth distributed antenna 390 is referred to as D-port # 2.

  If the third distributed antenna 380 and the fourth distributed antenna 390 transmit CSI-RS # 3 having the same pattern, the terminal distinguishes the third distributed antenna 380 and the fourth distributed antenna 390 from the CSI-RS # 3. I can't do that. And a terminal comes to measure the channel state between a terminal and the said distributed antenna from CSI-RS # 3. In this case, the third distributed antenna 380 and the fourth distributed antenna 390 are combined and referred to as D-port # 3. At this time, the time-frequency resources for CSI-RS transmission for each of C-port and D-port do not overlap each other and do not cause mutual interference.

  When a terminal first connects to the system in the LTE-A system, the terminal first acquires a cell ID by combining downlink time and frequency domain synchronization through cell search. Then, system information is received from the base station, and basic parameter values related to transmission / reception such as system bandwidth are acquired. Thereafter, the terminal performs a random access procedure in order to switch the link with the base station to a connected state. This will be described in detail with reference to FIG.

  FIG. 5 is a diagram illustrating a random access procedure according to the prior art.

  Referring to FIG. 5, as a first step 501 of the random access procedure, the UE transmits a random access preamble to the base station. Then, the base station measures the transmission delay value between the terminal and the base station, and adjusts the uplink synchronization. At this time, the terminal arbitrarily selects a random access preamble to be used within a predetermined random access preamble set. The initial transmission power of the random access preamble is determined by the path loss between the base station and the terminal measured by the terminal.

  In the second step 502, the base station transmits a timing adjustment command to the terminal from the transmission delay value measured in the first step. The base station also transmits uplink resources and power control commands used by the terminal as scheduling information. If the terminal does not receive the scheduling access information from the base station in the second step 502, the first step 501 is further performed.

  In the third step 503, the terminal transmits uplink data (message 3) including its own terminal ID to the base station through the uplink resource allocated in the second step 502. At this time, the transmission timing and transmission power of the terminal follow the command received from the base station in the second step 502. Finally, in step 504, if it is determined that the terminal has performed random access without collision with other terminals, the base station includes the ID of the terminal that transmitted uplink data in step 3503. Data (message 4) is transmitted to the terminal. If the terminal transmits a signal transmitted from the base station in the fourth step 504 from the base station, the terminal determines that the random access is successful.

  If the data transmitted from the terminal in the third stage 503 and the data of other terminals collide with each other and the base station fails to receive the data signal from the terminal, the base station does not transmit any more data to the terminal. . Accordingly, if the terminal does not receive the data transmitted from the base station in the fourth stage 504 during a certain time interval, the terminal determines that the random access procedure has failed and further starts from the first stage 501. If the random access is successful, the terminal sets the initial transmission power of the uplink data channel or control channel to be transmitted to the base station based on the transmission power value of the power controlled by the random access. To do.

Therefore, when a terminal performs a random access procedure in a system in which DAS or DAS and CAS are mixed, a method for efficiently determining random access preamble transmission power is required. Accordingly, an object of the present invention is to propose a method and related apparatus for effectively controlling power when a terminal performs random access when a DAS (Distributed Antenna System) is constructed based on the LTE-A system. There is.

  The present invention has been made to solve the aforementioned problems and provides at least the advantages described below.

  Accordingly, the present invention provides a method for determining a random access preamble transmission power in a random access process of a terminal in a system configured with DAS or DAS and CAS.

  Another aspect of the present invention provides a transmission power control method and apparatus for random access of a terminal in a DAS-based LTE-A system.

  A power control method for performing random access of a terminal in a mobile communication system according to the present invention includes a process of receiving control information including transmission power information for transmitting a random access preamble from a base station, and the transmission power information. And a step of calculating the transmission power using the transmission power, and a step of transmitting the random access preamble with the calculated transmission power.

  In addition, a terminal that controls power in the mobile communication system according to the present invention uses a reception unit that receives control information including transmission power information for transmitting a random access preamble from a base station, and uses the transmission power information. And a power supply controller for controlling the random access preamble transmission power and a transmission unit for transmitting the random access preamble with the controlled transmission power.

  The base station random access execution method in the mobile communication system according to the present invention includes a process of transmitting control information including antenna reference transmission power information for random access preamble transmission of a terminal to the terminal; A process of receiving a random access preamble, a process of transmitting a random access response corresponding to the random access preamble to the terminal, a process of receiving uplink data including the terminal identifier from the terminal, and the terminal identifier Transmitting data to the terminal.

  In addition, a base station performing random access in the mobile communication system according to the present invention generates a system information including a transceiver that transmits and receives signals to and from a terminal; and antenna reference transmission power information for random access preamble transmission of the terminal. And when receiving a random access preamble from the terminal, control is performed to transmit a random access response to the terminal, and when receiving uplink data (message 3) including the terminal identifier from the terminal, the terminal identifier is included. A power control controller for controlling to transmit data (message 4) to the terminal.

  According to the present invention, when a terminal performs random access using DAS (Distributed Antenna System), an effective power control method is provided, thereby preventing unnecessary power consumption of the terminal and minimizing the amount of interference on the system. Turn into.

FIG. 1 is a diagram illustrating a structure of a cellular mobile communication system in which a centralized antenna according to the prior art is arranged. FIG. 2 is a diagram illustrating a position of a CSI-RS transmitted from a base station to a terminal in an LTE-A system according to the prior art. FIG. 3 is a diagram showing an example of a system configuration in which CAS and DAS (Distributed Antenna System) are built together in a cellular mobile communication system according to the prior art. FIG. 4 is a diagram showing a system configuration in which central antennas according to the prior art are distributed in various regions in a cell. FIG. 5 is a diagram illustrating a random access procedure according to the prior art. FIG. 6 is a conceptual diagram illustrating a transmission power control method according to an embodiment of the present invention. FIG. 7 is a diagram illustrating a mobile communication system for transmission power control according to the first embodiment of the present invention. FIG. 8 is a diagram illustrating a random access procedure of a terminal according to the first embodiment of the present invention. FIG. 9 is a diagram illustrating a procedure in which a base station performs random access from a terminal according to the first embodiment of the present invention. FIG. 10 is a diagram illustrating a mobile communication system for transmission power control according to a second embodiment of the present invention. FIG. 11 is a diagram illustrating a random access procedure of a terminal according to the second embodiment of the present invention. FIG. 12 is a diagram illustrating a random access procedure of a base station according to the second embodiment of the present invention. FIG. 13 is a diagram illustrating a terminal device according to an embodiment of the present invention. FIG. 14 is a diagram illustrating a base station apparatus according to an embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, when it is determined that a specific description of a known function or configuration related to the description of the present invention can make the gist of the present invention unclear, a detailed description thereof will be omitted. The terms described later are terms defined in consideration of the function of the present invention, and can be changed according to the intention of the user, the operator or the custom. Therefore, the definition must be made based on the contents of the entire specification.

  Further, in specifically describing the embodiments of the present invention, the LTE-A (or Advanced E-UTRA) system is mainly targeted, but the main gist of the present invention is similar technical background and channel configuration. The present invention can be applied to other communication systems having a slight modification without departing from the scope of the present invention, and this can be determined at the discretion of those skilled in the technical field of the present invention. Let's go.

  The main gist of the present invention is a system in which a plurality of antennas are arranged in a cell, DAS or DAS (Distributed Antenna System) and CAS (Central Antenna System) are mixed, and between a terminal and each antenna port. A terminal can perform random access through a link having the best channel environment among multiple links. For this purpose, the terminal calculates transmission power information for transmitting the random access preamble using the antenna reference transmission power information received from the base station. Here, the antenna reference transmission power information includes a channel state reference signal for calculating a path loss between the terminal and each antenna, and a power adjustment parameter by an antenna located closest to the terminal. According to the present invention, there is provided an effective method in which transmission power of a random access preamble of a terminal is minimized, power consumption of the terminal is reduced, and interference is reduced.

  FIG. 6 is a conceptual diagram illustrating a transmission power control method according to an embodiment of the present invention.

  Referring to FIG. 6, the first antenna 610 and the second antenna 620 are geographically dispersed in the cell, and the path loss (PL) of the terminal 630 and the radio path of each antenna is PL1 and PL2. Assume that it is given. At this time, since PL1 is smaller than PL2 (PL1 <PL2), it can be said that the channel environment between the first antenna 610 and the terminal 630 is relatively better than the channel environment between the second antenna 620 and the terminal 630.

  The first antenna 610 and the second antenna 620 define independent CSI-RSs, respectively, so that the terminal 630 can measure the channel state for each antenna. In this case, the first antenna 610 may be called the antenna concept 1 of the logical concept, and the second antenna 620 may be called the antenna port 2 of the logical concept. If the same CSI-RS is transmitted from a plurality of physical antennas, the terminal 630 recognizes each physical antenna as one antenna port without partitioning.

  Pathloss is an index indicating whether the channel environment is good or bad, and the larger the value, the worse the channel environment. Pathloss is characterized by a small amount of change over time. Usually, the pathloss (PL) is calculated by [Expression 1] from an RS (Reference Signal) received from the base station by the terminal.

[Formula 1]
PL = referenceSignalPower-RSRP

  In [Formula 1], “referenceSignalPower” indicates the base station transmission power of the RS notified by the base station to the terminal through signaling, and “RSRP (Reference Signal Received Power)” indicates the reception of the RS measured by the terminal that received the RS. Indicates the signal strength.

  In order to overcome a channel environment that is not as good as the pathloss is large, the terminal must transmit the signal to be transmitted with a relatively large transmission power. However, if the transmission power of the terminal is large, the power consumption amount of the terminal becomes large as a result. In addition, the amount of interference increases, which adversely affects system performance. Accordingly, if the DAS mobile communication system can adaptively select the link having the best channel environment among the multiple links between the terminal and the plurality of antennas of the base station, and adjust the transmission power of the terminal, The amount of power consumption of the terminal is also reduced, and the amount of interference can also be reduced.

  FIG. 7 is a diagram illustrating a mobile communication system for transmission power control according to the first embodiment of the present invention. In particular, FIG. 7 illustrates a method in which a terminal adaptively sets random access preamble transmission power using a pathloss measured for each antenna.

  Referring to FIG. 7, the central antenna 710, the first distributed antenna 720, and the second distributed antenna 730 form one cell and communicate with the terminal 740. At this time, it is assumed that the central antenna 710, the first distributed antenna 720, and the second distributed antenna 730 transmit different patterns of CSI-RS. By transmitting different patterns of CSI-RS for each antenna, the terminal 740 can measure the channel state for each antenna.

  In FIG. 7, it is assumed that the central antenna 710 is mapped to C-port, the first distributed antenna 720 is mapped to D-port # 1, and the second distributed antenna 730 is mapped to D-port # 2. Then, it is assumed that the central antenna 710, the first distributed antenna 720, and the second distributed antenna 730 are connected to the central controller of the base station. Terminal 740 is geographically closest to first distributed antenna 720 and geographically furthest from second distributed antenna 730. Therefore, assuming that there is no difference in topographic features located between the terminal 740 and each antenna 710, 720, 730, the terminal 740 and the central antenna 710, the first distributed antenna 720, and the second distributed antenna 730 Each pathloss between the two has a relationship of PL2 <PL1 <PL3. At this time, PL1 is a pathloss between the terminal 740 and the central antenna 710, PL2 is a pathloss between the terminal 540 and the first distributed antenna 720, and PL3 is between the terminal 740 and the second distributed antenna 730. Pathloss is shown. The terminal can measure the pathloss of each antenna through a channel state reference signal (Channel State Information-Reference Signal; CSI-RS) defined for each antenna port.

The random access preamble transmission power P _PRACH of the terminal in the CAS scheme of the LTE-A system is _determined as [Expression 2] expressed in dBm units.

[Formula 2]
P _PRACH = min {P _CMAX , PREAMBLE_RECEIVED_TARGET_POWER + PL} [dBm]
-P _CMAX : Maximum transmission power allowed for the terminal, which is determined by the terminal class and higher level signaling settings.
-PREAMBLE_RECEIVED_TARGET_POWER: Random access preamble reception power required for the base station to receive the random access preamble, which is determined by parameters that are signaled higher.
-PL: pathloss between the base station and the terminal

  However, unlike CAS, since base station transmit / receive antennas are geographically dispersed in DAS, the pathloss between terminal 740 and each antenna 710, 720, 730 has different values. It becomes like this.

  Reference numbers 750, 760, and 770 in FIG. 7 indicate the transmission power of the pathloss between the terminal 740 and the central antenna 710, the terminal 740 and the first distributed antenna 720, and the terminal 740 and the second distributed antenna 730, respectively, in the CAS method. The case where it applies to [Formula 2] which calculates is shown. The calculated random access preamble transmission power of the terminal 740 can be a reference number 791, a reference number 792, and a reference number 793, respectively. The transmission power between the terminal 740 and the central antenna 710 is denoted by reference numeral 792, and the transmission power between the terminal 740 and the first distributed antenna 720 is denoted by reference numeral 791, and is transmitted between the terminal 740 and the second distributed antenna 730. The transmitted power is reference number 793.

  When the terminal determines and transmits the random access preamble transmission power as indicated by reference numeral 791, at least the first distributed antenna 720 can successfully receive the random access preamble. When the terminal 740 determines and transmits the random access preamble transmission power as indicated by reference numeral 792, at least the central antenna 710 can successfully receive the random access preamble. Also, when the terminal determines and transmits the random access preamble transmission power as indicated by reference numeral 793, at least the second distributed antenna 730 can successfully receive the random access preamble.

  The central antenna 710, the first distributed antenna 720, and the second distributed antenna 730 are connected to the central controller. Therefore, if the random access preamble reception is successful through at least one of the antennas from the viewpoint of the base station, it can be said that the random access preamble reception is finally successful. If the transmission power of the terminal 740 is minimized as much as possible, the power consumption of the terminal 740 can be minimized. In addition, since unnecessary interference does not occur from the viewpoint of the system, system performance deterioration is prevented. Therefore, in the first embodiment, a method is proposed in which the terminal 740 determines the transmission power using the smallest pathloss value among the pathlosses of each antenna. That is, the terminal can determine the random access preamble transmission power by substituting [Formula 2] with [Formula 3] when calculating the transmission power.

[Formula 3]
P _PRACH = min {P _CMAX , PREAMBLE_RECEIVED_TARGET_POWER + min (PL (k))} [dBm]
-PL (k) is a pathloss between the terminal and the k-th antenna port

  Reference numeral 780 in FIG. 7 indicates an example in which [Equation 3] is applied to determine the random access preamble transmission power of the terminal as reference numeral 790.

  FIG. 8 is a diagram illustrating a procedure for performing random access at a terminal according to the first embodiment of the present invention.

  Referring to FIG. 8, in step 801, the UE obtains a cell ID by combining downlink time and frequency synchronization through cell search. In step 802, the terminal receives system information including antenna reference transmission power information for transmitting a random access preamble from the base station. Here, the UE performs pathloss (PL) measurement of each antenna (antenna port), which is antenna reference transmission power information for transmitting the system bandwidth, the random access related parameter, and the random access preamble through the received system information. Basic parameter values related to transmission / reception such as CSI-RS pattern information are acquired.

  In step 803, the terminal measures and compares the pathloss between the terminal and each antenna (antenna port) from the acquired CSI-RS pattern information. Next, in step 804, the terminal determines transmission power required for random access preamble transmission using [Formula 3]. That is, the terminal measures the pathloss between the terminal and each antenna, and confirms the smallest pathloss among the measured pathloss values. The terminal then applies the smallest confirmed pathloss value to Equation 3 to determine the transmission power.

  In step 805, the UE transmits a random access preamble with the determined transmission power. Thereafter, in step 806, the UE determines whether a random access response is received from the base station. If the random access response is not received within a certain period of time, the terminal returns to step 805 and further performs random access preamble transmission. However, if the random access response is received in step 806, the terminal transmits message 3 to the base station using the scheduling information included in the random access response in step 807.

  Next, in step 808, the terminal determines whether message 4 has been received from the base station. If message 4 is not received even after a predetermined time has elapsed, the terminal moves to step 805 and further performs random access preamble transmission. However, if message 4 is received in step 808, all random access procedures at the terminal end successfully.

  FIG. 9 is a diagram illustrating a procedure in which a base station performs random access from a terminal according to the first embodiment of the present invention.

  Referring to FIG. 9, in step 901, the BS transmits basic parameter values related to transmission and reception such as system information, random access related parameters, and CSI-RS pattern information of each antenna (antenna port) to the terminal. . In step 902, the base station confirms whether a random access preamble has been received from the terminal. If the random access preamble is not received, the base station returns to step 902 and waits until the random access preamble is received from the terminal.

  On the other hand, if the random access preamble is successfully received, the base station generates a random access response including a timing adjustment command and scheduling information for the terminal from the random access preamble received from the terminal in step 903, and transmits the random access response to the terminal. . In step 904, the base station determines whether message 3 has been received from the terminal. If message 3 is successfully received, the base station transmits message 4 to the terminal in step 905. On the other hand, if message 3 is not received, the base station returns to step 902 and waits until the next random access preamble is received from the terminal.

  As a modified example of the first embodiment, the base station may designate and signal the random access preamble that the terminal must use without arbitrarily selecting what random access preamble the terminal uses. it can. The random access preamble specified by the base station and notified to the terminal is referred to as a “designated random access preamble”. In a random access procedure using 'designated random access preamble', there is no possibility of random access colliding between different terminals. Accordingly, steps 807 and 808 of FIG. 8 in the terminal random access procedure corresponding to this and steps 904 and 905 of FIG. 9 in the random access procedure of the base station are unnecessary.

  In addition, a random access procedure may be required when executing a handover that is a procedure for switching between cells of a terminal. More specifically, if the base station instructs the terminal to perform handover from cell A to cell B, the terminal performs random access to cell B and proceeds to perform communication in cell B. . In this case, as a modification of the first embodiment, in step 802, the base station notifies the terminal of a CSI-RS pattern information set for PL measurement of each antenna for cells A and B and a plurality of cells.

  For example, the base station sets CSI-RS pattern information set = {CSI-RS pattern information # 1, CSI-RS pattern information # 2, CSI-RS pattern information # 3, CSI-RS pattern information # 4, CSI-RS pattern. Information # 5, CSI-RS pattern information # 6} is notified to the terminal. Then, the base station additionally informs through the signaling which CSI-RS pattern information the terminal must actually use for the PL measurement.

  If the terminal is located in cell A, the base station uses CSI-RS pattern information # 1, CSI-RS pattern information # 2, CSI-RS used by the terminal for PL measurement within the CSI-RS pattern information set. Notify RS pattern information # 3. And when instruct | indicating the hand-over of a terminal from the cell A to the cell B, a base station uses CSI-RS pattern information # 4 and CSI-RS pattern which a terminal uses for PL measurement within a CSI-RS pattern information set. Information # 5 and CSI-RS pattern information # 6 can be notified. Through this process, the base station can notify the terminal of CSI-RS pattern information for PL measurement of each antenna in the entire system without partitioning between cells. Also, the base station can notify the terminal to use a part of CSI-RS pattern information for PL measurement depending on the situation. The terminal performs PL measurement using the CSI-RS pattern information notified from the base station, and determines the transmission power. In this case, as shown in [Formula 3], the terminal can determine the transmission power using the smallest PL value among the PLs of the antennas corresponding to the CSI-RS pattern notified to the terminal. . Or the average value with respect to PL of each antenna corresponding to the CSI-RS pattern notified of the terminal can be determined as PL, and the transmission power can be determined.

  FIG. 10 is a diagram illustrating a mobile communication system for transmission power control according to a second embodiment of the present invention. In particular, FIG. 10 illustrates a method for determining random access preamble transmission power when a terminal is signaled with parameters for compensating a channel environment with a predetermined antenna from a base station.

  Referring to FIG. 10, an example in which a central antenna 1010, a first distributed antenna 1020, and a second distributed antenna 1030 constitute one cell and communicate with a terminal 1040. Indicates. Each central antenna 1010 and the first and second distributed antennas 1020 and 1030 transmit different patterns of CSI-RS. That is, the central antenna 1010 is mapped to C-port, the first distributed antenna 1020 is mapped to D-port # 1, and the second distributed antenna 1030 is mapped to D-port # 2. It is assumed that all the central antennas 1010 and the first and second distributed antennas 1020 and 1030 are connected to the central controller of the base station.

  In the second embodiment, assuming that the terminal performs pathloss measurement for one antenna, the terminal measures the pathloss between the C-port covering the entire cell area and the terminal. Accordingly, the base station signals an additional power adjustment parameter Δ for adjusting the random access preamble transmission power of the terminal based on the terminal position information. Then, the terminal determines the random access preamble transmission power according to the following [Equation 4].

[Formula 4]
P _PRACH = min {P _CMAX , PREAMBLE_RECEIVED_TARGET_POWER + PL + Δ} [dBm]
-P _CMAX : Maximum transmission power allowed for the terminal, which is determined by the terminal class and higher level signaling settings.
-PREAMBLE_RECEIVED_TARGET_POWER: Random access preamble reception power required for the base station to receive the random access preamble, which is determined by parameters that are signaled higher.
-PL: pathloss between base station and terminal
-Δ: An additional power adjustment parameter for adjusting the random access preamble transmission power of the terminal, which can be changed according to the location information of the terminal.

  Reference numeral 1050 in FIG. 10 indicates an example in which the terminal determines the random access preamble transmission power as the reference numeral 1080 using the additional power adjustment of Δ1060 according to [Equation 4]. Here, Δ is a power adjustment parameter generated based on an antenna close to the terminal based on the position information of the terminal. Thus, Δ can have a value of '0' or a negative number.

  If the terminal calculates the transmission power of the random access preamble according to [Equation 2], the reference number 1070 is obtained. However, if the terminal calculates the random access preamble transmission power using Δ, the transmission power is consumed by Δ1060 less than the transmission power calculated by [Equation 2].

  FIG. 11 is a diagram illustrating a procedure for performing random access of a terminal according to the second embodiment of the present invention.

  Referring to FIG. 11, in step 1101, the UE obtains a cell ID by combining downlink time and frequency synchronization through cell search. In step 1102, the terminal receives system information including antenna reference transmission power information for transmitting a random access preamble from the base station. The terminal obtains basic parameter values related to transmission and reception such as system bandwidth, random access related parameters, and Δ information for random access preamble transmission power adjustment that is antenna reference transmission power information. To do. Δ is a parameter that is set so that the base station confirms the location information of the terminal and controls the transmission power based on the antenna close to the confirmed location of the terminal.

  In step 1103, the UE transmits the random access preamble according to [Formula 4] using the acquired random access related parameter, Δ information that is a power adjustment parameter for adjusting the random access preamble transmission power, and the pathloss measurement value for C-port. Determine the transmission power required for In step 1104, the terminal transmits a random access preamble with the determined transmission power.

  Next, in step 1105, the UE determines whether a random access response is received from the base station. If the random access response is not received within a certain period of time, the terminal returns to step 1104 and further performs random access preamble transmission. However, if the random access response is received in step 1105, the UE moves to step 1106 and transmits message 3 to the base station according to the scheduling information included in the random access response.

  In step 1107, the terminal determines whether message 4 is received from the base station. If message 4 is not received even after a predetermined time has elapsed, the terminal moves to step 1104 and further performs random access preamble transmission. However, if message 4 is received in step 1107, all random access procedures are successfully completed.

  FIG. 12 is a diagram showing a random access procedure of the base station according to the second embodiment.

  Referring to FIG. 12, in step 1201, the base station transmits basic parameter values related to transmission / reception such as system information, random access related parameters, and Δ information for random access preamble transmission power adjustment to the terminal. In step 1202, the base station determines whether a random access preamble has been received from the terminal. If the random access preamble is not received, the base station waits until a random access preamble is received from the terminal in step 1202.

  On the other hand, if the random access preamble is successfully received, the base station generates a random access response including a timing adjustment command and scheduling information for the terminal from the random access preamble received from the terminal in step 1203 and transmits the random access response to the terminal. . In step 1204, the base station determines whether message 3 is received from the terminal. If the message 3 is not received, the base station moves to step 1202 and waits until the next random access preamble is received from the terminal. On the other hand, if message 3 is successfully received, the base station transmits message 4 to the terminal in step 1205. The terminal can end the random access procedure by successfully receiving message 4.

  The second embodiment can be variously modified. As an example, the terminal does not arbitrarily select what random access preamble to use, and the base station can specify and signal the random access preamble that the terminal must use. The random access preamble specified by the base station and notified to the terminal is referred to as a “designated random access preamble”. In this case, the base station can reduce the additional signaling overhead by not knowing Δ separately but implicitly knowing from the “designated random access preamble”. For example, the relationship between the “designated random access preamble” and Δ can be defined in advance as follows, and the base station and the terminal can be operated in common.

Designated random access preamble 1 to designated random access preamble k1 → Δ1
Designated random access preamble k1 + 1 to designated random access preamble k2 → Δ2
Designated random access preamble k2 + 1 to designated random access preamble k3 → Δ3
...

  Thus, in the random access procedure using the “designated random access preamble”, there is no possibility of random access collision between different terminals. Accordingly, steps 1106 and 1107 in FIG. 11 relating to the random access procedure of the terminal, which are procedures corresponding thereto, and steps 1204 and 1205 in FIG. 12 relating to the random access procedure of the base station can be deleted.

  FIG. 13 is a diagram illustrating a terminal device according to an embodiment of the present invention.

  Referring to FIG. 13, for random access preamble transmission, a terminal generates a random access preamble generator 1310 that generates a random access preamble to be transmitted, and RE (resource) a signal to be transmitted. An RE mapper (RE mapper) 1320 to be mapped to an element and a random access preamble generated by the terminal is mapped to a frequency region designated in advance through the RE mapper 1320, and then passed through an IFFT (Inverse Fast Fourier Transform) processing 1330. IF (intermediate frequency) and RF (radiof frequency) Passes through NCY) processing unit 1340, is transmitted to the base station through the transmission unit (TX) 1350.

  Then, the terminal receives system information from the base station through a receiving unit (RX) 1360. At this time, system information includes system bandwidth, random access related parameters and antenna reference transmission power information, CSI-RS pattern information of each antenna, Δ information for random access preamble transmission power adjustment, etc. Contains parameter values.

  The terminal checks the pathloss between the base station and the terminal or the pathloss between each antenna and the terminal from a path loss measuring device (Pathloss estimator) 1370. The terminal acquires a random access related parameter provided from the base station through a parameter acquisition unit 1380. Next, the terminal adjusts the random access preamble transmission power of the terminal using a power control controller 1390 using the confirmed pathloss and random access related parameters. Specifically, the terminal determines the random access preamble transmission power value by the method described in the first embodiment or the second embodiment of the present invention. In addition, the power control controller 1390 controls the random access preamble generator 1310 or the IF / RF processing unit 1340 to adjust the power of the random access preamble.

  FIG. 14 is a diagram illustrating a base station apparatus according to an embodiment of the present invention.

  Referring to FIG. 14, the base station includes an RF / IF unit 1402 that performs RF / IF signal processing on a signal received from a terminal through a reception unit (RX) 1401, an FFT unit 1403 that performs FFT (Fast Fourier Transform) processing, An RE demapper 1404, a random access preamble detector 1405, a power control controller 1406, and the like.

  The power control controller 1406 generates an appropriate power control parameter for random access preamble transmission according to the location of the terminal, and applies it to a control information generator 1407. The control information generator 1407 receives power control parameters input from the power control controller 1406 and information such as whether the base station has successfully received the random access preamble from the random access preamble detector 1405, Control information corresponding to this is generated. The control information generated in this way is given error correction capability through an encoder 1408, and is composed of modulation symbols by a modulator 1409, and then is generated by a RE mapper (RE mapper) 1410 for a predetermined time- Mapped to frequency resource. Next, the data passes through an IFFT processing 1411, passes through an IF (intermediate frequency) processing unit and an RF (radiof frequency) processing unit 1412, and is transmitted to a terminal through a transmission unit (TX) 1413.

  The embodiments of the present invention disclosed in this specification and the drawings are merely illustrative examples for facilitating the technical contents of the present invention and helping the understanding of the present invention. It is not intended to be limited. It will be apparent to those skilled in the art to which the present invention pertains that other variations based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100 first cell 110 second cell 120 third cell 130 central antenna 140 first terminal 150 second terminal 340 first terminal 350 second terminal 360 first distributed antenna 370 second distributed antenna 380 third distributed antenna 390 fourth distributed Antenna 400 first cell 410 second cell 420 third cell 430 first central antenna 431 second central antenna 432 third central antenna 433 fourth central antenna 434 fifth central antenna 440 first terminal 450 second terminal 460 first dispersion Antenna 470 Second distributed antenna 480 Third distributed antenna 490 Fourth distributed antenna 540 Terminal 610 First antenna 620 Second antenna 630 Terminal 710 Central antenna 710 Central antenna 720 First distributed antenna 730 Second distributed antenna 740 Terminal 1310 Random access Rumble generator 1320 Mapper 1340 Processing unit 1370 Path loss measuring device 1380 Parameter acquisition unit 1390 Power control controller 1402, FFT unit 1403, RE unit 1404 Demapper 1405 Random access preamble detector 1406 Power control controller 1407 Control information generator 1408 Encoder 1409 Modulator 1410 Mapper 1411 Processing 1412 Processing unit RX 1360 Reception unit RX 1401 Reception unit TX 1350 Transmission unit TX 1413 Transmission unit

Claims (16)

In a power control method for performing random access of a terminal in a mobile communication system,
Receiving reference signal information about a plurality of reference signals corresponding to a plurality of antenna ports from a base station;
Using the reference signal information to measure a plurality of path loss values for the plurality of antenna ports;
Using the minimum value among the plurality of path loss value, the step of calculating the transmission power,
The power control method of the terminal, which comprises a, and transmitting the random access preamble transmission power the calculated. The method of claim 1, wherein the reference signal information is related to a channel state reference signal for each antenna port . The reference signal information is
The terminal power control method according to claim 2, comprising pattern information of the channel state reference signal for measuring a path loss for each antenna port . The method of claim 1 , wherein the mobile communication system includes a distributed antenna system . The method of claim 1 , wherein the plurality of reference signals are received through a corresponding antenna port among the plurality of antenna ports . The transmission power (P _PRACH ) is
P _PRACH = min {P _CMAX , PREAMBLE_RECEIVED_TARGET_POWER + min (PL (k)} [dBm]
The _PCMAX represents the maximum output power of the terminal based on the terminal class and higher layer signaling settings,
The PREAMBLE_RECEIVED_TARGET_POWER represents a random access preamble received power required by a base station to receive the random access preamble, which is determined by a setting of the higher layer signaling.
2. The terminal power control method according to claim 1, wherein PL (k) represents a path loss value between the terminal and the k ^th antenna port . In a terminal that controls power in a mobile communication system,
A receiving unit for receiving reference signal information about a plurality of reference signals corresponding to a plurality of antenna ports from a base station;
A power supply control controller that measures a plurality of path loss values for the plurality of antenna ports using the reference signal information and calculates a random access preamble transmission power using a minimum value among the plurality of path loss values When,
Terminal, characterized in that it comprises a and a transmission unit for transmitting the random access preamble transmission power the calculated. The terminal according to claim 7, wherein the reference signal information relates to a channel state reference signal for each antenna port . The reference signal information is
The terminal according to claim 8, comprising pattern information of the channel state reference signal for measuring a path loss for each antenna port . The terminal according to claim 7 , wherein the mobile communication system includes a distributed antenna system . The terminal of claim 7 , wherein the plurality of reference signals are received through a corresponding antenna port among the plurality of antenna ports . The power control controller is
The transmission power (P _PRACH ) is
P _PRACH = min {P _CMAX , PREAMBLE_RECEIVED_TARGET_POWER + min (PL (k)} [dBm]
The _PCMAX represents the maximum output power of the terminal based on the terminal class and higher layer signaling settings,
The PREAMBLE_RECEIVED_TARGET_POWER represents a random access preamble received power required by a base station to receive the random access preamble, which is determined by a setting of the higher layer signaling.
The PL (k), the terminal according to claim 7, characterized in that to represent the path loss value between the terminal and k ^th antenna port. In a random access execution method of a base station in a mobile communication system,
Transmitting reference signal information about a plurality of reference signals corresponding to a plurality of antenna ports to a terminal;
Receiving a random access preamble transmitted with transmission power from the terminal ,
The transmission power is calculated by the terminal using a minimum value among a plurality of path loss values for the plurality of antenna ports,
The base station random access execution method, wherein the plurality of path loss values are measured by the terminal using the reference signal information . The reference signal information relates to a channel state reference signal for each antenna port;
The reference signal information includes pattern information of the channel state reference signal for measuring a path loss for each antenna port,
The mobile communication system includes a distributed antenna system,
The method of claim 13, wherein the plurality of reference signals are received through a corresponding antenna port among the plurality of antenna ports . In a base station that performs random access in a mobile communication system,
A transceiver for transmitting and receiving signals to and from the terminal;
The transceiver is controlled to transmit reference signal information related to a plurality of reference signals corresponding to a plurality of antenna ports to the terminal, and the transmission / reception is performed to receive a random access preamble transmitted with transmission power from the terminal. a power control controller for controlling the machine; wherein,
The transmission power is calculated by the terminal using a minimum value among a plurality of path loss values for the plurality of antenna ports,
The base station characterized in that the plurality of path loss values are measured by the terminal using the reference signal information . The reference signal information relates to a channel state reference signal for each antenna port;
The reference signal information includes pattern information of the channel state reference signal for measuring a path loss for each antenna port,
The mobile communication system includes a distributed antenna system,
The base station of claim 15, wherein the plurality of reference signals are received through a corresponding antenna port among the plurality of antenna ports .