JP2011259238A - Radio communication system, radio base station, radio terminal and communication control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system, a radio base station, a radio terminal, and a communication control method which are capable of scheduling which can avoid deterioration of communication quality.SOLUTION: A radio terminal 300 determines transmission power of a PUSCH based on scheduling information on a DL-PL and a UL. The radio terminal 300 calculates PHR from the transmission power of the PUSCH, and notifies a radio base station 100 of the calculated PHR information. The radio base station 100 estimates the transmission power of the PUSCH actually transmitted by the radio terminal 300 based on the PHR notified by the radio terminal 300 and the maximum transmission power of the radio terminal 300. The radio base station 100 performs scheduling of a next uplink based on the estimated transmission power.

Description

  The present invention relates to a radio communication system, a radio base station, a radio terminal, and a communication control method.

  In an LTE (Long Term Evolution) mobile communication system defined by 3GPP, a propagation loss (PL) in a radio communication between a radio base station (eNB) and a radio terminal (UE) and a radio base station are set. Based on the scheduling information to be transmitted, the transmission power of a physical uplink shared channel (hereinafter referred to as PUSCH) used by the wireless terminal to transmit data is calculated. Specifically, it is calculated based on the following formula (1) (see Non-Patent Document 1).

In Equation (1), P _PUSCH (i) indicates the transmission power of PUSCH. i indicates a subframe number. P _CMAX indicates the maximum transmission power of the wireless terminal. M _PUSCH (i) indicates the number of Resource Blocks (hereinafter referred to as RBs) assigned to the radio terminal by the radio base station in subframe i. P _{o _PUSCH} indicates an initial value of transmission power per RB specific to the wireless terminal. α represents a coefficient for controlling the rate of path loss compensation. PL indicates a propagation loss of radio waves between the radio base station and the radio terminal. The propagation loss is a parameter indicating how much the transmission power from the transmission side is attenuated on the reception side. Δ _TF (i) indicates a coefficient determined from a modulation and coding scheme (MCS). f (i) represents a transmission power correction term by a TPC (Transmit Power Control) command transmitted from the radio base station to the radio terminal.

  In LTE, in order for a radio terminal to transmit a signal in the uplink, the radio base station allocates radio resources (frequency band and modulation / coding scheme) necessary for uplink communication to the radio terminal in advance. Scheduling must be done. Specifically, the radio base station determines the frequency band (number of RBs) and modulation / coding scheme (MCS) for the radio terminal according to the radio wave propagation situation between the radio base station and the radio terminal. To do.

  When performing scheduling, the radio base station calculates SINR (Signal to Interference and Noise Ratio) using the transmission power of the radio terminal and the average interference power and thermal noise measured by the radio base station. The radio base station knows the radio wave propagation status based on the calculated SINR. In this case, the radio base station cannot acquire information indicating the transmission power of the PUSCH when the radio terminal actually transmits data from the radio terminal. For this reason, the radio base station must estimate the transmission power of the PUSCH when the radio terminal actually transmits data. In this case, the radio base station uses the above equation (1) to calculate the PUSCH transmission power for the radio terminal, and uses the calculated PUSCH transmission power for the PUSCH when the radio terminal actually transmits data. Is estimated as the transmission power.

3GPP, TS36.321 (V9.2.0), “Medium Access Control (MAC) protocol specification,” Mar. 2010.

When calculating the transmission power of the PUSCH for the wireless terminal using the above equation (1), the wireless base station applies the uplink PL as a propagation loss (hereinafter referred to as “PL” as appropriate) to obtain the transmission power of the PUSCH. calculate. On the other hand, when calculating the transmission power of PUSCH using the above equation (1), the wireless terminal calculates the transmission power of PUSCH by applying downlink PL as PL. For this reason, when the uplink PL and the downlink PL are different, the value of the PUSCH transmission power obtained from the equation (1) is different between the radio base station and the radio terminal. The case where the uplink PL is different from the downlink PL is, for example, the situation shown in (A) and (B) below. These situations are generally assumed.
(A) When the radio terminal moves at high speed, fading fluctuation in the radio environment between the radio base station and the radio terminal becomes severe, and the fading gain differs greatly between the uplink and the downlink.
(B) In an environment where an AF relay node having a different uplink amplification factor and downlink amplification factor is relayed between the wireless base station and the wireless terminal, a signal is transmitted between the wireless base station and the wireless terminal. When transmitted.
Thus, if the PUSCH transmission power calculated by the radio base station is different from the PUSCH transmission power calculated by the radio terminal, the radio base station cannot appropriately perform scheduling for the radio terminal. For this reason, the communication quality between the radio base station and the radio terminal is deteriorated.

  Therefore, an object of the present invention is to provide a radio communication system, a radio base station, a radio terminal, and a communication control method capable of scheduling that can avoid deterioration in communication quality.

  In order to solve the above-described problems, the present invention has the following features. A first feature of the present invention includes a wireless terminal (wireless terminal 300) and a wireless base station (wireless base station 100), and the wireless terminal determines downlink propagation loss and the wireless base station. A transmission power determination unit (transmission power determination unit 331) that determines transmission power (PUSCH transmission signal) for transmitting a data signal based on information related to uplink scheduling and the transmission power determination unit Based on transmission power, a calculation unit (PHR calculation unit 341) that calculates the power headroom of the wireless terminal, and a transmission unit (communication unit 302) that transmits information indicating the power headroom calculated by the calculation unit. The radio base station includes an acquisition unit (communication unit 102) for acquiring information indicating Power Headroom, and uplink scheduling And a control unit (control unit 103) that performs a data signal of the wireless terminal based on the maximum transmission power of the wireless terminal and information indicating the power headroom acquired by the acquisition unit. The gist of the present invention is a wireless communication system that estimates transmission power and performs scheduling of the next uplink for the wireless terminal based on the estimated transmission power.

  In such a wireless communication system, the wireless base station can estimate the transmission power of the PUSCH transmitted by the wireless terminal from information indicating the power headroom notified from the wireless terminal. Therefore, the radio base station can appropriately estimate the PUSCH transmission power of the radio terminal even in a radio environment in which the propagation loss between the uplink and the downlink is different. Accordingly, the radio base station can perform scheduling that can avoid deterioration in communication quality.

  The second feature of the present invention is that, when the acquisition unit acquires information indicating Power Headroom, the wireless base station indicates the maximum transmission power of the wireless terminal and the Power Headroom acquired by the acquisition unit. Based on the information, the transmission power of the data signal in the wireless terminal is estimated, and the next uplink scheduling for the wireless terminal is performed based on the estimated transmission power.

  As described above, when the radio base station acquires information indicating the power headroom from the radio terminal, the radio base station can always estimate the transmission power of the PUSCH transmitted by the radio terminal from the information indicating the power headroom.

  According to a third aspect of the present invention, the wireless terminal further includes a notification unit that notifies the maximum transmission power of the wireless terminal, and the control unit of the wireless base station receives the wireless terminal notified from the notification unit The gist of the present invention is to estimate the transmission power of data in the wireless terminal based on the maximum transmission power and the information indicating the power headroom acquired by the acquisition unit. In this case, for example, at the start of communication with the radio base station, the radio terminal notifies the radio base station of information regarding the maximum transmission power of the radio terminal. The radio base station holds (stores) information related to the maximum transmission power of the radio terminal notified from the radio terminal while communication with the radio terminal is pending.

  A fourth feature of the present invention includes: a control unit that performs uplink scheduling; and an acquisition unit that acquires information indicating power headroom of a wireless terminal in uplink communication, wherein the control unit includes the wireless terminal Based on the maximum transmission power and the information indicating the power headroom acquired by the acquisition unit, the transmission power of the data signal in the wireless terminal is estimated, and the uplink for the wireless terminal is estimated based on the estimated transmission power The gist of the present invention is that the radio base station is configured to perform scheduling.

  According to a fifth aspect of the present invention, there is provided a transmission power determination unit that determines transmission power for transmitting data based on downlink propagation loss and information on uplink scheduling determined by a radio base station, A calculation unit that calculates a power headroom based on transmission power determined by the transmission power determination unit, and a transmission unit that transmits information indicating the power headroom calculated by the calculation unit to the radio base station. The gist is that it is a wireless terminal.

  A sixth feature of the present invention is a first feature in which a wireless terminal determines transmission power for transmitting data based on downlink propagation loss and information on uplink scheduling determined in a wireless base station. A second step in which the wireless terminal calculates a power headroom of the wireless terminal based on the transmission power determined in the first step, and the wireless base station is calculated in the second step. Based on the third step of acquiring information indicating Power Headroom, and the wireless base station based on the maximum transmission power of the wireless terminal and the information indicating the Power Headroom acquired in the third step. A fourth step of estimating the transmission power of the radio base station, and the radio base station was estimated in the fourth step Based on the transmission power, and summarized in that the a fifth step of performing scheduling of the next uplink radio terminal, a communication control method comprising.

  According to the features of the present invention, the radio base station can perform scheduling that can avoid deterioration in communication quality.

1 is an overall schematic configuration diagram of a wireless communication system according to an embodiment of the present invention. It is a figure which shows the structure of the radio | wireless terminal of the radio | wireless communications system which concerns on embodiment of this invention. It is a figure which shows the structure of AF relay node. It is a figure which shows the structure of the radio base station of the radio | wireless communications system which concerns on embodiment of this invention. 5 is a flowchart showing an operation of the radio communication system according to the embodiment of the present invention. It is a figure which shows the throughput characteristic of the uplink in the radio | wireless terminal concerning embodiment of this invention. 6 is a flowchart illustrating an operation of a wireless communication system according to another embodiment of the present invention.

  Next, an embodiment of the present invention will be described with reference to the drawings. Specifically, (1) the configuration of the wireless communication system, (2) the operation of the wireless communication system, (3) the operation and effect, and (4) other embodiments will be described. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

(1) Configuration of radio communication system
(1.1) Overall schematic configuration of wireless communication system
FIG. 1 is an overall schematic configuration diagram of a wireless communication system 1 according to an embodiment of the present invention. The radio communication system 1 has a configuration based on LTE-Advanced, which is positioned as a fourth generation (4G) mobile phone system, for example.

  As shown in FIG. 1, a radio communication system 1 includes a radio base station (MeNB) 100 that forms a large cell (for example, a macro cell) MC1, and AF (Amplify and Forward) as a communication relay device installed in a building or the like. ) Relay node 200 and radio terminal (UE) 300 located in large cell MC1. The AF relay node 300 is also referred to as a repeater.

  In the wireless communication system 1 illustrated in FIG. 1, downlink wireless communication from the wireless base station 100 to the wireless terminal 300 via the AF relay node 200 is performed. Further, uplink radio communication from the radio terminal 300 to the radio base station 100 via the AF relay node 200 is performed.

(1.2) Configuration of wireless terminal
FIG. 2 is a diagram showing a configuration of the wireless terminal 300 of the wireless communication system 1 according to the embodiment of the present invention.

  As illustrated in FIG. 2, the wireless terminal 300 includes a control unit 301, a communication unit 302, and an antenna 303. The control unit 301 is configured using, for example, a CPU (Central Processing Unit) and the like, and controls various functions provided in the wireless terminal 300.

  The control unit 301 includes a DL propagation loss calculation unit 311 that calculates downlink propagation loss, a UL scheduling information recognition unit 321 that recognizes information related to uplink scheduling determined by the radio base station 100, and a DL propagation loss calculation unit. A transmission power determining unit 331 that determines transmission power for transmitting a data signal based on downlink propagation loss calculated by 311 and information on uplink scheduling recognized by the UL scheduling information recognition unit 321; A PHR calculation unit 341 that calculates a power headroom (hereinafter referred to as PHR) of the wireless terminal 300 based on the transmission power determined by the determination unit 331;

  The DL propagation loss calculation unit 311 determines between the radio base station 100 and the radio terminal 300 based on the received power measurement value when the radio terminal 300 receives a signal and the known transmission power value of the radio base station 100. The downlink propagation loss is calculated. The propagation loss includes distance attenuation, shadowing loss, and feature passing loss.

  The UL scheduling information recognition unit 321 recognizes information related to uplink scheduling, which is scheduled by the radio base station 100 and notified from the radio base station 100 to the radio terminal 300. The information regarding scheduling indicates a frequency band and a modulation / coding scheme used by the radio terminal 300 in uplink communication. Details of scheduling in the radio base station 100 will be described later.

  The transmission power determination unit 331 transmits a data signal based on the downlink propagation loss calculated by the DL propagation loss calculation unit 311 and the information related to uplink scheduling recognized by the UL scheduling information recognition unit 321. Determine the transmission power. The transmission power in this case is the transmission power of PUSCH (Physical Uplink Shared Channel).

Specifically, the transmission power determination unit 331 determines (calculates) the transmission power of the PUSCH based on the above equation (1). In this case, the transmission power determination unit 331 applies the downlink propagation loss calculated by the DL propagation loss calculation unit 311 to the PL in Expression (1). Also, the transmission power determining unit 331 applies the frequency band (in this case, the number of RBs) recognized by the UL scheduling information recognizing unit 321 to the M _PUSCH (i) in Expression (1). Also, the transmission power determination unit 331 applies the modulation / coding scheme used in uplink communication recognized by the UL scheduling information recognition unit 321 to Δ _TF (i) in Equation (1).

The PHR calculation unit 341 calculates the PHR of the wireless terminal 300 based on the transmission power determined by the transmission power determination unit 331. Specifically, it is calculated based on the following formula (2). PHR is indicated in decibel values.

In Expression (2), PH (i) represents the PHR of the radio terminal 300 in the subframe i. P _CMAX indicates the maximum transmission power of the radio terminal UE. P _PUSCH (i) indicates the transmission power of PUSCH in subframe i calculated by Expression (1) in transmission power determination section 313. _{M PUSCH (i), P o} _ PUSCH, the coefficient alpha, PL, the Δ _TF (i), and f (i) is omitted because it is same as the above explanation.

  The PHR calculated by the PHR calculation unit 341 indicates transmission power that the radio terminal 300 can increase. A large PHR indicates that the transmission power that can be increased by the wireless terminal 300 is large. A small PHR indicates that the transmission power that can be increased by the wireless terminal 300 is small.

  The communication unit 302 transmits information indicating the PHR calculated by the PHR calculation unit 341 (hereinafter referred to as PHR information) via the antenna 303. The communication unit 302 is configured with RF or the like. Thereby, the radio terminal 300 can notify the radio base station 100 of the PHR information calculated by the PHR calculation unit 341.

(1.3) Configuration of AF relay node
FIG. 3 is a diagram showing the configuration of the AF relay node 200.

  The AF relay node 200 is, for example, a 1 input 1 output SISO (Single Input Single Output) type. In addition, the AF relay node is not limited to the SISO type AF relay node but may be a MIMO (Multiple Input Multiple Output) type AF relay node.

  As shown in FIG. 3, the AF relay node 200 includes an antenna 201, an antenna 202, a donor-side radio communication unit 203, a service-side radio communication unit 204, and a control unit 205. The control unit 205 includes a downlink amplification unit 206 and an uplink amplification unit 207. The amplification factor of the downlink amplification unit 206 and the amplification factor of the uplink amplification unit 207 are different. In the present embodiment, the amplification factor of the uplink amplification unit 207 is set to be higher than the amplification factor of the downlink amplification unit 206.

  A communication stream signal transmitted from the radio base station 100 is received by the antenna 201. A signal received by the antenna 201 is input to the downlink amplification unit 206 of the control unit 205 via the donor-side radio communication unit 203.

  The downlink amplifying unit 206 amplifies the signal input from the donor-side radio communication unit 203 and outputs the amplified signal to the service-side radio communication unit 204. The service-side wireless communication unit 204 outputs the signal amplified by the downlink amplification unit 206 to the antenna 202. The signal amplified by the downlink amplification unit 206 is retransmitted from the antenna 202 as a downlink signal.

  A communication stream signal transmitted from the wireless terminal 300 is received by the antenna 202. A signal received by the antenna 202 is input to the uplink amplifying unit 207 of the control unit 205 via the service-side wireless communication unit 204.

  The uplink amplifying unit 207 amplifies the signal input from the service side wireless communication unit 204 and outputs the amplified signal to the donor side wireless communication unit 203. The donor-side radio communication unit 203 outputs the signal amplified by the uplink amplification unit 207 to the antenna 201. The signal amplified by the uplink amplifying unit 207 is retransmitted from the antenna 201 as an uplink signal.

(1.4) Configuration of radio base station
FIG. 4 is a diagram showing a configuration of the radio base station 100 of the radio communication system according to the embodiment of the present invention.

  As illustrated in FIG. 4, the radio base station 100 includes an antenna 101, a communication unit 102, a control unit 103, and a storage unit 104. The antenna 101 receives a signal from the wireless terminal 300 via the AF-relay node 200. The communication unit 102 is configured by RF or the like. The control unit 103 is configured using, for example, a CPU (Central Processing Unit) or the like, and controls various functions provided in the radio base station 100. Information indicating the maximum transmission power of the wireless terminal 300 is stored in the storage unit 104.

  The communication unit 102 receives a signal from the wireless terminal 300 transmitted via the AF relay node 200 via the antenna 101. The signal received by the communication unit 102 includes the PHR information of the wireless terminal 300 described above. A signal received by the communication unit 102 is sent to the control unit 103. In addition, the communication unit 102 transmits information on the radio resources (frequency band (number of RBs) and modulation / coding scheme) allocated to the radio terminal 300 by the scheduling unit 123 to the radio terminal 300. Details of scheduling in the scheduling unit 123 will be described later.

  The control unit 103 includes a UE transmission power estimation unit 113 that estimates transmission power of the radio terminal 300 and a scheduling unit 123 that performs uplink scheduling.

UE transmission power estimation section 113, based on the PHR information of radio terminal 300 and the information indicating the maximum transmission power of radio terminal 300 stored in storage section 104, the transmission power (PUSCH of the data signal) of data signal in radio terminal 300. Estimate the transmission power. Specifically, UE transmission power estimation section 113 estimates the transmission power of radio terminal 300 by the following equation (3).

In Equation (3), P _PUSCH (i) represents the transmission power of the radio terminal 300. P _CMAX indicates the maximum transmission power of the radio terminal UE, and is stored in the storage unit 104. PH (i) indicates the PHR of the wireless terminal 300 in subframe i. This PHR is notified from the radio terminal 300 to the radio base station 100.

The scheduling unit 123 performs uplink scheduling at the next transmission timing for the radio terminal 300 based on the transmission power (P _PUSCH (i)) of the radio terminal 300 estimated by the UE transmission power estimation unit 113. That is, the radio base station allocates uplink radio resources (frequency band (number of RBs) and modulation / coding scheme) in consideration of the transmission power of radio terminal 300. The scheduling unit 123 performs scheduling based on the scheduling policy of the wireless communication system. In this case, the scheduling unit 123 performs scheduling so as to guarantee the communication quality of the wireless terminal 300.

(2) Operation of wireless communication system
Next, the operation of the wireless communication system will be described. FIG. 5 is a flowchart showing an operation of the radio communication system according to the embodiment of the present invention.

  In step S1, the transmission power determination unit 331 of the radio terminal 300 is calculated by the DL propagation loss calculation unit 311 and information related to uplink scheduling notified from the radio base station 100 and recognized by the UL scheduling information recognition unit 312. The transmission power (PUSCH transmission power) for transmitting the data signal is determined based on the downlink propagation loss.

  In step S <b> 2, the PHR calculation unit 341 of the wireless terminal 300 calculates the PHR of the wireless terminal 300 based on the transmission power determined by the transmission power determination unit 331. The communication unit 302 transmits the signal of the PHR information calculated by the PHR calculation unit 341 using PUCCH (Physical Uplink Control Channel).

  Next, a signal (a signal including PHR information) transmitted from the radio terminal 300 is relayed by the AF relay node 200 and transmitted to the radio base station 100 (step S3). The AF relay node 200 amplifies the signal from the radio terminal 300 and retransmits it to the radio base station 100.

  In step S <b> 4, the radio base station 100 transmits the data signal transmission power in the radio terminal 300 based on the maximum transmission power of the radio terminal 300 and the PHR information received from the radio terminal 300 via the AF relay node 200. (PUSCH transmission power) is estimated.

  In step S5, the radio base station 100 allocates radio resources required for the next uplink transmission in the radio terminal 300 based on the transmission power of the radio terminal 300 estimated in step S4. When the radio base station 100 allocates uplink radio resources to the radio terminal 300 in step S5, the radio base station 100 includes information indicating the allocated radio resources in a PDCCH (Physical Downlink Control Channel) and directs the radio terminal 300 toward the radio terminal 300. Send.

  A signal transmitted from the radio base station 100 (a signal including uplink radio resource allocation information) is relayed by the AF relay node 200 and transmitted to the radio terminal 300 (step S6). The AF relay node 200 amplifies the signal from the radio base station 100 and retransmits it to the radio terminal 300.

  When receiving the signal from the radio base station 100 retransmitted from the AF relay node 200 and recognizing the uplink radio resource allocation information from the received signal, the radio terminal 300 recognizes the uplink radio resource allocation information after 4 subframes and performs the process of step S1. I do. The wireless communication system repeats the processes in steps S1 to S6 described above.

(3) Action and effect
In the wireless communication system according to the present embodiment, the wireless terminal 300 calculates the PUSCH transmission power based on the downlink propagation loss and the uplink scheduling information determined by the wireless base station 100, and further determines the PUSCH transmission power. The PHR of the radio terminal 300 is calculated from the transmission power, and the calculated PHR information is notified to the radio base station 100. Based on the maximum transmission power of the radio terminal 300 and the PHR notified from the radio terminal 300, the radio base station 100 estimates the transmission power of the PUSCH actually transmitted by the radio terminal 300. Thereby, the radio base station 100 can appropriately estimate the PUSCH transmission power of the radio terminal 300 even in a radio environment in which the propagation loss between the uplink and the downlink is different.

  Therefore, the radio base station 100 allocates uplink radio resources related to the radio terminal 300 based on appropriately estimated PUSCH transmission power, and therefore can perform scheduling that can avoid deterioration in communication quality.

  In the present embodiment, a case has been described in which, in the AF relay node 200, the amplification factor of the uplink signal is higher than the amplification factor of the downlink signal. FIG. 6 is a diagram showing uplink throughput characteristics in the radio terminal 300 according to the embodiment of the present invention. In FIG. 6, the vertical axis indicates the uplink throughput in the wireless terminal. In FIG. 6, “Avg” indicates an average UE (wireless terminal) throughput, “5%” indicates a throughput of 5 percent UE, and “Cluster” indicates an average throughput of an indoor UE. The uplink throughput of the wireless terminal 300 in the present embodiment is indicated by “Estimated by PHR” in FIG. “Estimated PL” shown in FIG. 6 indicates the throughput of the wireless terminal when scheduling is performed based on the above-described uplink propagation loss.

  FIG. 6 shows the uplink throughput of the radio terminal 300 when the radio base station 100 estimates the PUSCH transmission power based on the uplink propagation loss and the radio terminal 300 based on the PHR of the radio terminal 300. The measurement results are shown. According to the simulation result, the radio base station 100 estimates the PUSCH transmission power based on the PHR of the radio terminal 300, compared to the case where the radio base station 100 estimates the PUSCH transmission power based on the uplink propagation loss. It is recognized that the throughput characteristics are improved in the case. This is because the radio base station 100 estimates the PUSCH transmission power based on the PHR of the radio terminal 300, so that even if the amplification factor of the AF relay node 200 is different, the PUSCH transmission power determined by the radio terminal 300 is wireless. This is considered to be because the base station 100 can correctly estimate, and thereby the radio base station 100 can select an appropriate modulation / coding scheme (MCS).

(4) Other embodiments
As described above, the present invention is shown by the above description of the embodiments. However, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  In the above-described embodiment, the AF relay node 200 is provided between the radio terminal 300 and the radio base station 100. For example, as illustrated in FIG. 7, the AF relay node 200 is provided between the radio terminal 300 and the radio base station 100. The present invention can be similarly applied even in a wireless environment in which the AF relay node 200 is not provided.

  In the embodiment described above, the radio base station 100 stores information indicating the maximum transmission power of the radio terminal 300 in the storage unit 104 in advance, and when the PHR information is acquired from the radio terminal 300, the storage unit 104 The transmission power of the PUSCH of the wireless terminal 300 is estimated based on the maximum transmission power and PHR of the wireless terminal 300 stored in step 1. However, the following embodiment may be used.

  Specifically, the radio terminal 300 notifies the radio base station 100 of the maximum transmission power of the radio terminal 300 (a part of the control unit 301. The notification unit is not shown). Is further provided. The control unit 103 of the radio base station 100 stores information indicating the maximum transmission power of the radio terminal 300 notified by the notification unit of the radio terminal 300 in the storage unit 104. Based on the PHR information acquired by the communication unit 102 and the information indicating the maximum transmission power of the wireless terminal 300 previously stored in the storage unit 104, the wireless base station 100 transmits data transmission power ( PDSCH transmission power) is estimated.

  In this case, the radio terminal 300 notifies the radio base station 100 of information indicating the maximum transmission power of the radio terminal 300, for example, when communication with the radio base station 100 is started (for example, when random access is started). Note that the radio base station 100 holds (stores) information indicating the maximum transmission power of the radio terminal 300 notified from the radio terminal 300 while the communication with the radio terminal 300 is pending. When the communication connection with the wireless terminal 300 is released, the stored information indicating the maximum transmission power of the wireless terminal 300 may be deleted. Also, in this case, the radio base station 100 uses the radio base station adjacent to the radio base station 100 (the radio base indicated in the neighbor list) as the information indicating the maximum transmission power of the radio terminal 300 notified from the radio terminal 300. Station, hereinafter referred to as an adjacent radio base station). In this case, the radio base station 100 notifies at least information indicating the maximum transmission power of the radio terminal 300 to the adjacent radio base station that is a candidate for the handover destination of the radio terminal 300. As a result, when the radio terminal 300 is handed over from the currently connected radio base station 100 to the handover destination adjacent radio base station, the handover destination adjacent radio base station of the radio terminal 300 Similar to the base station 100, the scheduling using the information indicating the maximum transmission power of the radio terminal 300 can be executed.

  In the embodiment described above, when the radio base station 100 acquires the PHR information from the radio terminal 300, the radio base station 100 always uses the acquired PHR information to estimate the PUSCH transmission power of the radio terminal 300. However, the following embodiment may be adopted.

  The radio base station 100 takes a log for a predetermined period and stores the PHR periodically notified from the radio terminal 300 in the storage unit 104. When the radio base station 100 no longer notifies the PHR information from the radio terminal 300 at a predetermined timing (predetermined period), the radio base station 100 uses the past PHR information stored in the storage unit 104 based on the past PHR information. Estimate the transmission power. In addition, when the radio base station 100 does not notify the PHR information at a predetermined timing (predetermined period) from the radio terminal 300, the radio base station 100 provisionally transmits the PUSCH that the radio terminal transmits based on the uplink propagation loss. The power may be estimated.

  In the above-described embodiment, the wireless communication system is configured based on LTE-Advanced, but may be configured based on other communication standards such as 3GPP-Release 9.

  Thus, it should be understood that the present invention includes various embodiments and the like not described herein. Therefore, the present invention is limited only by the invention specifying matters in the scope of claims reasonable from this disclosure.

1: wireless communication system, 100: wireless base station, 200: AF relay node, 300: wireless terminal, 101: antenna, 102: communication unit, 103: control unit, 104: storage unit, 113: UE transmission power estimation unit, 123: Scheduling unit, 201, 202: Antenna, 203: Donor side wireless communication unit, 204: Service side wireless communication unit, 205: Control unit, 206: Downlink amplification unit, 207: Uplink amplification unit, 301: Control unit, 302: communication unit, 303: antenna, 311: DL propagation loss calculation unit, 321: uplink scheduling information recognition unit, 331: transmission power determination unit, 341: PHR calculation unit.

Claims (6)

A wireless terminal and a wireless base station;
The wireless terminal is
A transmission power determination unit that determines transmission power for transmitting a data signal based on downlink propagation loss and information on uplink scheduling determined by the radio base station;
A calculation unit that calculates a power headroom of the wireless terminal based on the transmission power determined by the transmission power determination unit;
A transmission unit that transmits information indicating the power headroom calculated by the calculation unit;
The radio base station is
An acquisition unit for acquiring information indicating the Power Headroom;
A controller that performs uplink scheduling,
The controller is
Based on the maximum transmission power of the wireless terminal and information indicating the power headroom acquired by the acquisition unit, the transmission power of the data signal in the wireless terminal is estimated,
A wireless communication system, wherein scheduling of a next uplink for the wireless terminal is performed based on the estimated transmission power. The radio base station is
When the acquisition unit acquires information indicating the Power Headroom, transmission of a data signal in the wireless terminal based on the maximum transmission power of the wireless terminal and the information indicating the Power Headroom acquired by the acquisition unit Estimate power,
The radio communication system according to claim 1, wherein next uplink scheduling for the radio terminal is performed based on the estimated transmission power. The wireless terminal is
A notification unit for notifying the maximum transmission power of the wireless terminal;
The control unit of the radio base station is
The transmission power of data in the wireless terminal is estimated based on the maximum transmission power of the wireless terminal notified from the notification unit and the information indicating the power headroom acquired by the acquisition unit. The wireless communication system according to 1. A controller that performs uplink scheduling;
An acquisition unit that acquires information indicating the power headroom of the wireless terminal in uplink communication,
The controller is
Based on the maximum transmission power of the wireless terminal and information indicating the power headroom acquired by the acquisition unit, the transmission power of the data signal in the wireless terminal is estimated,
A radio base station that performs uplink scheduling for the radio terminal based on the estimated transmission power. A transmission power determining unit that determines transmission power for transmitting data based on downlink propagation loss and information on uplink scheduling determined by the radio base station;
A calculation unit for calculating Power Headroom based on the transmission power determined by the transmission power determination unit;
A wireless terminal comprising: a transmission unit that transmits information indicating the power headroom calculated by the calculation unit to the wireless base station. A first step in which a radio terminal determines transmission power for transmitting data based on downlink propagation loss and information on uplink scheduling determined in the radio base station;
A second step in which the wireless terminal calculates a power headroom of the wireless terminal based on the transmission power determined in the first step;
A third step in which the radio base station acquires information indicating the power headroom calculated in the second step;
A fourth step in which the wireless base station estimates the transmission power of data in the wireless terminal based on the maximum transmission power of the wireless terminal and the information indicating the power headroom acquired in the third step;
A communication control method including: a fifth step in which the radio base station performs next uplink scheduling for the radio terminal based on the transmission power estimated in the fourth step.