KR102557996B1 - Device and method for controlling transmission power - Google Patents

Abstract

A transmission power control method according to an exemplary embodiment of the present disclosure may include calculating a remaining power level of a third period included in a first period and future from the present based on an allowable power level of the first period and a remaining power level of a second period in the past from the present, calculating a transmission power level of the third period based on the remaining power level of the third period and a target power level, and generating a power control signal for determining a power level of a transmission signal unit based on the transmission power level of the third period.

Description

Transmission power control device and method {DEVICE AND METHOD FOR CONTROLLING TRANSMISSION POWER}

The technical idea of the present disclosure relates to wireless communication, and in detail, to a transmission power control apparatus and method.

In a wireless communication system, since radio frequency (RF) signal transmission between a base station (e.g., Node B) and user equipment (UE) is easily affected by path loss, shadow fading, etc., the base station and user equipment need to have appropriate transmission power so that Quality of Service (QoS) does not deteriorate. As a wireless communication device, the user device may output an RF signal according to transmission power for signal transmission, and a user of the user device may be exposed to an RF electromagnetic field by the RF signal. Energy absorbed by the user from the RF electromagnetic field may increase as the transmit power increases.

The technical spirit of the present disclosure provides a method and apparatus for controlling transmission power used for wireless transmission in a wireless communication device by considering energy absorbed by a user.

In order to achieve the above object, a method for controlling transmission power used for wireless transmission in a wireless communication device according to an aspect of the technical idea of the present disclosure includes calculating a remaining power level of a third period included in a first period and based on a remaining power level of a second period in the past from the present and an allowable power level of the first period, calculating a transmission power level of the third period based on the remaining power level of the third period and a target power level, and based on the transmission power level of the third period It may include generating a power control signal that determines a power level of a transmission signal unit.

A transmission power control method according to an aspect of the technical idea of the present disclosure may include calculating remaining radiated energy included in a first period and based on the allowable radiated energy of a first period and used energy radiated for wireless transmission during a second period past from the present and a third period in the future from the present, calculating a transmit power level based on the remaining radiated energy and a target power level, and generating a power control signal that determines a power level of a transmit signal unit based on the transmit power level.

An apparatus and method for controlling transmission power according to the technical idea of the present disclosure can substantially limit energy emitted from a wireless communication device for a certain period of time while maintaining service quality of wireless transmission.

In addition, the transmission power control apparatus and method according to the technical idea of the present disclosure can effectively limit the energy absorbed by the user from the wireless communication device by considering the state of the wireless communication device.

In addition, the transmit power control apparatus and method according to the technical concept of the present disclosure can maintain the transmit power at the maximum while satisfying the allowable value of the SAR.

1 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure.
2 shows transmit power levels used in a transmission unit over time according to an exemplary embodiment of the present disclosure.
3A and 3B are diagrams illustrating examples of calculating a remaining power level according to exemplary embodiments of the present disclosure.
4 illustrates an example of calculating a remaining power level by dividing the second period of FIGS. 3A and 3B into a plurality of sub-periods according to an exemplary embodiment of the present disclosure.
5 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure.
6 is a flow chart illustrating an example operation of the remaining power calculator of FIG. 5 according to an exemplary embodiment of the present disclosure.
7 is a block diagram illustrating an example of the transmit power calculator of FIG. 1 according to an exemplary embodiment of the present disclosure.
8 is a flowchart illustrating operation of the transmission power calculator of FIG. 7, according to an exemplary embodiment of the present disclosure.
9 is a block diagram illustrating an example of the transmit power calculator of FIG. 1 according to an exemplary embodiment of the present disclosure.
10 is a flowchart illustrating operation of the transmit power calculator of FIG. 9, according to an exemplary embodiment of the present disclosure.
11 is a graph illustrating a change in a remaining power level over time according to an exemplary embodiment of the present disclosure.
12 is a flowchart illustrating a method of setting a target power level according to an exemplary embodiment of the present disclosure.
13 is a diagram illustrating a cumulative power level in a second period including periods with no wireless transmission, according to an exemplary embodiment of the present disclosure.
14 illustrates examples of controlling transmission power of a transmission unit over time according to an exemplary embodiment of the present disclosure.
15 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure.
16 is a flowchart illustrating a method for controlling transmission power in a wireless communication device according to an exemplary embodiment of the present disclosure.
17 is a flowchart illustrating a method for calculating a remaining power level according to an exemplary embodiment of the present disclosure.
18 is a flow chart illustrating a method for calculating a transmit power level according to an exemplary embodiment of the present disclosure.
19 is a graph illustrating an example in which transmission power is controlled according to a transmission power control method according to an exemplary embodiment of the present disclosure.
20 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure.
21 shows an exemplary block diagram of a wireless communication device according to an exemplary embodiment of the present disclosure.

1 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure. As shown in FIG. 1 , a user equipment 1000 and a base station 2000 may communicate through a downlink (DL) channel 10 and an uplink (UL) channel 20 .

A user equipment (UE) 1000 is a wireless communication device, which may be fixed or mobile, and may refer to various devices capable of transmitting and receiving data and/or control information by communicating with the base station 2000. For example, the user device 1000 may be referred to as a terminal equipment, a mobile station (MS), a mobile terminal (MT), a user terminal (UT), a subscribe station (SS), a wireless device, a handheld device, and the like. A base station (BS) 2000 may generally refer to a fixed station that communicates with user equipment and/or other base stations, and may exchange data and control information by communicating with user equipment and/or other base stations. For example, the base station 2000 may also be referred to as a Node B, an evolved-Node B (eNB), a Base Transceiver System (BTS), and an Access Pint (AP).

A wireless communication network between user equipment 1000 and base station 2000 can support multiple users to communicate by sharing available network resources. For example, in a wireless communication network, code division multiple access (CDMA), frequency division multiple access (FDMA), time division multiple access (TDMA), orthogonal frequency division multiple access (OFDMA), single carrier frequency division multiple access (SC-FDMA) Information can be transmitted in various ways, such as access.

The transmit power of the user device 1000 may be adjusted by an uplink (UL) transmit power control (TPC) command transmitted from the base station 2000 to the user device 1000 through the downlink channel 10. For example, the base station 2000 may transmit a TPC command to the user device 1000 based on the estimated SIR in order to maintain a signal-to-interference ratio (SIR) of an RF signal received from the user device 1000 at a target level. The user device 1000 may adjust (ie, increase, decrease, or maintain) the power of RF signals transmitted to the base station 2000 through the uplink channel 20 based on the received TPC command.

The transmission power of the user device 1000 may be related to energy emitted from the user device 1000 as well as power consumption of the user device 1000 . That is, a strong electromagnetic field can be formed by the RF signals generated by the user device 1000 with high transmit power, and a user exposed to the electromagnetic field can absorb energy from the user device 1000 . A specific absorption rate (SAR) may refer to an energy absorption rate by a human body when exposed to an RF electromagnetic field. The SAR by an electronic device is regulated not to exceed a certain level, and in a wireless communication device such as the user device 1000, the SAR can be adjusted by adjusting the transmission power. However, since transmission power is closely related to the quality of service (QoS) of the user equipment 1000 and the base station 2000, the transmission power can be controlled by considering both the SAR and QoS. For example, the transmit power control apparatus (e.g., the transmit power controller 1300 of FIG. 1) and the method according to an exemplary embodiment of the present disclosure maintain the transmit power to the maximum while satisfying the limits of the SAR, thereby maintaining the quality of service (QoS).

Referring to FIG. 1 , a user device 1000 may include an antenna 1100, a transceiver module 1200, and a transmission power controller 1300. The transceiver module 1200 may include a receiver 1220 and a transmitter 1240, and the transmission power controller 1300 may include a remaining power calculator 1320, a transmission power calculator 1340, and a control signal generator 1360. In this specification, the transmission power controller 1300 may also be referred to as a transmission power control device. Each of the components included in the user device 1000 may be a hardware block including an analog circuit and/or a digital circuit, or a software block including a plurality of instructions executed by a processor or the like.

The receiver 1220 of the transceiver module 1200 may receive RF signals received from the base station 2000 through the antenna 1100 and extract a TPC command from the received RF signals. For example, the receiver 1220 may include a demodulator and a decoder, and may extract a TPC command by demodulating and decoding RF signals received through the antenna 1100 . In addition, the receiver 1220 may generate a requested power level (P_REQ) representing the transmission power of the user equipment 1000 requested by the base station 2000 according to the extracted TPC command. Unlike shown in FIG. 1 , according to an exemplary embodiment of the present disclosure, the receiver 1220 may output the extracted TPC command, and the requested power level P_REQ may be generated from the TPC command outside the receiver 1220 (e.g., the transmit power controller 1300).

The transmitter 1240 of the transceiver module 1200 may receive the power control signal C_POW from the transmission power controller 1300 and adjust the power of the RF signal output through the antenna 1100 according to the power control signal C_POW. That is, the transceiver module 1200 may differently adjust the power level (TX Power) for each transmission unit (TX Unit) in response to the power control signal (C_POW). For example, a transmission unit of LTE (Long Term Evolution) may have a length of 1 ms corresponding to a subframe, and a transmission unit of Wideband Code Division Multiple Access (WCDMA) and High Speed Downlink Packet Access (HSDPA) may have a length of 0.667 ms corresponding to one slot.

The transceiver module 1200 may form a beam used in, for example, LTE and mmWave to the antenna 1100 . For example, the antenna 1100 may be a multi-antenna including a plurality of antennas, and the transceiver module 1200 may form a beam on the antenna 1100 by adjusting phases of RF signals output to each of the antennas. In addition, even when the antenna 1100 is a single antenna, a beam can be formed, and the transceiver module 1200 can adjust the shape of a beam formed on the antenna 1100. As will be described later with reference to FIGS. 5 and 15, the beam formed by the antenna 1100 may be closely related to the electromagnetic absorption rate (SAR), and accordingly, the user device 1000 may control the transmission power or change the shape of the beam in consideration of the beam formed by the antenna 1100.

As shown in FIG. 1 , the remaining power calculator 1320 of the transmission power controller 1300 may include the allowable power level P_TOT. For example, the remaining power calculator 1320 may include a storage space for storing the allowable power level P_TOT, such as a memory or a register. The allowable power level P_TOT may be determined based on an allowable SAR value of the user device 1000, and as will be described later with reference to, for example, FIG.

The remaining power calculator 1320 may receive the transmit power level P_TX from the transmit power calculator 1340, and may calculate and output the remaining power level P_REM based on the allowable power level P_TOT and the transmit power level P_TX. The remaining power level (P_REM) may refer to a transmission power level available for wireless transmission by the user equipment 1000 for a certain period from now to the future. Details of the operation of the remaining power calculator 1320 will be described later with reference to FIGS. 3A, 3B, and 4 .

The transmission power calculator 1340 may receive the remaining power level P_REM from the remaining power calculator 1320 and may receive the requested power level P_REQ from the receiver 1220 of the transceiver module 1200 . The transmit power calculator 1340 may calculate and output the transmit power level P_TX based on the remaining power level P_REM and the requested power level P_REQ. For example, the transmit power calculator 1340 may output the same transmit power level P_TX as the requested power level P_REQ according to the remaining power level P_REM, or may output a transmit power level P_TX lower than the requested power level P_REQ due to the SAR. Details of the operation of the transmit power calculator 1340 will be described later with reference to FIGS. 7 to 13 .

The control signal generator 1360 may receive the transmit power level P_TX from the transmit power calculator 1340 and generate the power control signal C_POW based on the transmit power level P_TX. For example, the transmission power level P_TX output by the transmission power calculator 1340 may correspond to one transmission unit or a series of transmission units. As described above, since the transmitter 1240 of the transceiver module 1200 adjusts the transmission power of the transmission unit in response to the power control signal C_POW, when the transmission power level P_TX corresponds to one transmission unit, the control signal generator 1360 generates one power control signal C_POW according to the transmission power level P_TX, while generating a control signal when the transmission power level P_TX corresponds to a series of transmission units. The unit 1360 may sequentially generate a series of power control signals C_POW based on the transmit power level P_TX. Details of the operation of the control signal generator 1360 will be described later with reference to FIG. 14 .

When adjusting the transmission power for wireless transmission in a wireless communication device in consideration of the SAR, the SAR may not be satisfied if the reduction in transmission power is insignificant, and the quality of service (QoS) may deteriorate if the reduction in transmission power is excessive. In addition, when the amount of change in transmission power is fixed, the magnitude of transmission power may unnecessarily rise and fall repeatedly. However, as described above, the transmission power controller 1300 according to an exemplary embodiment of the present disclosure may calculate the remaining power level P_REM based on the allowable power level P_TOT and the transmission power level P_TX determined according to the allowable value of the SAR, and may determine the transmission power level P_TX based on the remaining power level P_REM. Accordingly, it is possible to substantially limit the energy emitted for a certain period of time while maintaining the quality of service (QoS) of wireless transmission, and the maximum transmission power can be maintained while satisfying the allowable value of the SAR.

2 illustrates power levels of a transmission unit over time according to an exemplary embodiment of the present disclosure. As described above with reference to FIG. 1 , different power levels may be applied for each transmission unit (eg, one subframe in case of LTE). In addition, the allowable power level (P_TOT) may refer to the total transmit power level available for wireless transmission by a wireless communication device (e.g., the user device 1000 of FIG. 1) for a certain period of time so as to satisfy the allowable value of the SAR.

Referring to FIG. 2 , the first period PER1 may have a length corresponding to n transmission units (TX Units), and the allowable power level (P_TOT _PER1 ) may refer to the maximum total transmit power level usable by the user device 1000 for wireless transmission during the first period (PER1), that is, the sum of the power levels (TX Power) of the transmit units (TX Units) so as to satisfy the allowable electromagnetic wave absorption rate (SAR _limit ). As shown in FIG. 2 , the allowable power level (P_TOT _PER1 ) may be expressed as f (SAR _limit ), which is a function of the allowable electromagnetic wave absorption rate (SAR _limit ) in the human body. The SAR may be determined due to various factors such as the distance between the user and the wireless communication device and other sources generating energy radiated from the wireless communication device, and accordingly, the function 'f' of FIG. 2 may further include one or more additional parameters in addition to the allowable SAR _limit .

When the sum of transmit power levels used by the wireless communication device (eg, the user device 1000 in FIG. 1 ) for the transmission unit during the first period PER1 satisfies the allowable power level P_TOT _PER1 or less, the SAR by the wireless communication device may satisfy the allowable SAR _limit (ie, may be less than the allowable SAR _limit ). Similarly, the average power level P_AVG may be defined by dividing the allowable power level P_TOT _PER1 by 'n', the number of transmission units included in the first period PER1, and if the average of the transmission power levels in the first period PER1 satisfies the average power level P_AVG or less, the SAR by the wireless communication device may satisfy the allowable SAR _limit . That is, the allowable power level P_TOT included in the remaining power calculator 1320 of FIG. 1 may be the allowable power level P_TOT _PER1 of the first period PER1.

The wireless communication device may be required to satisfy the allowable power level P_TOT _PER1 in a first arbitrary period PER1. For example, the wireless communication device may require the sum of transmit power levels in each of t_0 to t_n, t_1 to t_n_1, and t_2 to t_n+2 to be equal to or less than the allowable power level (P_TOT _PER1 ). That is, the sum of transmission power levels included in a moving window having a width of the first period PER1 may be required to be equal to or less than the allowable power level P_TOT _PER1 . As will be described below, the transmit power control apparatus and method according to exemplary embodiments of the present disclosure may control the transmit power to satisfy the allowable electromagnetic wave absorption rate (SAR _limit ) by calculating the remaining power level based on the power level used for wireless transmission and the allowable power level (P_TOT _PER1 ) of the first period (PER1). For example, as shown in FIG. 2 , the remaining power level (P_REM _PER1 ) of the first period (PER1) may be calculated as the sum of the difference between the average power level (P_AVG) and the power level (TX Power) of the transmission unit (TX Unit) (ie, P_REM _PER1 = ∑ _PER1 (P_AVG - TX Power)), and the remaining power level (P_REM _PER1 ) of the first period (PER1) The transmission power may be controlled so that the transmission power becomes equal to or greater than zero (ie, P_REM _PER1 ≥ 0).

3A and 3B are diagrams illustrating examples of calculating a remaining power level according to exemplary embodiments of the present disclosure. As described above with reference to FIG. 1 , the remaining power calculator 1320 of the transmission power controller 1300 may calculate the remaining power level P_REM based on the allowable power level P_TOT and the transmission power level P_TX.

Referring to FIGS. 3A and 3B , the second period PER2 may be a period from a specific point in the past to the present, and a third period PER3 may be a period from the present included in the first period PER1 to a specific point in the future. The remaining power level _{P_REM PER3} of the third period PER3 may be calculated based on the allowable power level P_TOT PER3 of the third period PER3 and the remaining power level P_TOT _PER2 of the second period PER2. For example, the allowed power level P_TOT _PER3 of the third period PER3 may be calculated from the allowed power level P_TOT PER1 of the first period PER1 based on the ratio between the first period PER1 and the third period PER3, and the remaining power level P_REM _PER3 of the third period PER3 is the allowed power level P_TOT _PER3 of the third period _PER3 and the second period ( PER2) may be calculated based on the remaining power level (P_REM _PER2 ). That is, the remaining power level P_REM _PER3 of the third period PER3 from the present to the future may be varied by the remaining power level P_REM _PER2 of the second period PER2 from the present to the past. For example, the transmission power controller 1300 of FIG. 1 may calculate the remaining power level P_REM _PER2 of the second period PER2, calculate the remaining power level P_REM _PER3 of the third period PER3 from the remaining power level P_REM PER2 of the second period PER2, and output the calculated remaining power level P_REM _PER3 as the remaining power level P_REM. That is, the remaining power level P_REM output by the transmission power controller 1300 of FIG. 1 may be the remaining power level P_REM _PER3 of the third period PER3 . By calculating the remaining power level P_REM _PER3 of the third period PER3, the transmission power level to be used during the third period PER3 may be calculated (eg, by the transmission power calculator 1340 of FIG. 1).

Referring to FIG. 3A , the first period PER1 may be equal to the sum of the second period PER2 and the third period PER3. Accordingly, the remaining power level P_REM _PER3 of the third period PER1 may match the sum of the allowable power level P_TOT _PER3 of the third period PER3 and the remaining power level P_REM _PER2 of the second period PER2. That is, the remaining power level P_REM _PER3 of the third period PER3 can be expressed as in [Equation 1] below.

As wireless transmission continues, the first to third periods PER1 to PER3 may move, and accordingly, the remaining power level P_REM _PER2 of the second period PER2 may be referred to as a moving sum of the remaining power levels of the second period PER2. Also, the remaining power level P_REM _PER2 of the second period PER2 may be calculated from the allowable power level P_TOT _PER1 of the first period PER1 and the transmission power level P_TX. For example, as described above with reference to FIG. 2 , the average power level P_AVG may be calculated from the allowed power level P_TOT _PER1 of the first period PER1 , and the remaining power level P_REM _PER2 of the second period PER2 may be calculated by summing the differences between the average power level P_AVG and the transmission power levels P_TX included in the second period PER2 (ie, P_REM _PER2 = ∑ _PER2 (P_AVG - P_TX)).

Referring to FIG. 3B , the sum of the second period PER2 and the third period PER3 may be greater than the first period PER1 . That is, the power level of the transmission unit prior to the first period PER1 may be used to calculate the remaining power level P_REM of the third period PER3. Accordingly, as shown in FIG. 3B , the remaining power level P_REM _PER3 of the third period PER3 may be a weighted sum of the remaining power level P_REM _PER2 of the second period PER2 and the allowed power level P_TOT _PER3 of the third period PER3. That is, the remaining power level P_REM _PER3 of the third period PER3 can be expressed as in [Equation 2] below.

In [Equation 2], the weight 'W' may be determined according to the lengths of the first to third periods PER1 to PER3. For example, when the first period PER1 and the second period PER2 each have a length corresponding to 1000 transmission units and the third period PER3 has a length corresponding to one transmission unit, the weight 'W' may be '999/1000'.

According to an exemplary embodiment of the present disclosure, the remaining power level P_REM _PER2 of the second period PER2 shown in FIGS. 3A and 3B may be a value generated by filtering the remaining power levels included in the second period PER2. For example, the remaining power calculator 1320 of FIG. 1 may include a finite impulse response (FIR) filter or an infinite impulse response (IIR) filter, and the remaining power level P_REM _PER2 of the second period PER2 may be a value obtained by passing the remaining power levels through such a digital filter.

According to an exemplary embodiment of the present disclosure, the remaining power level P_REM _PER2 of the second period PER2 shown in FIGS. 3A and 3B may be calculated using a moving average. For example, the remaining power level P_REM _PER2 of the second period PER2 may be calculated as a product of a moving average calculated by a cumulative moving average or an exponential moving average of the remaining power levels included in the second period PER2 and the number of transmission units (or transmission power levels) included in the second period PER2. In this way, when the remaining power level P_REM PER2 of the second period _PER2 is calculated using a cumulative moving average or an exponential moving average, the previous remaining power level P_REM _PER2 and the added remaining power level instead of using all remaining power levels used during the second period PER2 to calculate the remaining power level P_REM _PER2 of the second period PER2. Since , storage space for calculating the remaining power level (P_REM _PER2 ) can be saved.

FIG. 4 illustrates an example of calculating a remaining power level by dividing the second period PER2 of FIGS. 3A and 3B into a plurality of sub-periods according to an exemplary embodiment of the present disclosure. As described above with reference to FIGS. 3A and 3B , the remaining power level P_REM _PER2 of the second period PER2 may be calculated from the remaining power levels included in the second period PER2.

Referring to FIG. 4 , partial remaining power levels (P_REM _{PER2_1} to P_REM _{PER2 _m} ) of a plurality of sub-periods SP_1 to SP_m may be calculated. As shown in FIG. 4B, the partial remaining power may be calculated by accumulating the difference between the transmission power included in the sub-period and the average power level (P_AVG). The partial residual power calculated in this way may have a positive value or a negative value. The remaining power level P_REM _PER2 of the second period PER2 may be the sum of a plurality of partial remaining powers P_REM _{PER2 _1} to P_REM _{PER2 _m} . The remaining power level P_REM _PER3 of the third period PER3 may be calculated as shown in [Equation 3] below using the remaining power level P_REM _PER2 and the average power level P_AVG of the second period PER2.

In [Equation 3], 'l' may be the number of transmission units included in the third period PER3. Accordingly, in order to calculate the remaining power level P_REM _PER2 of the second period PER2, instead of storing all the remaining power levels of the second period PER2, a plurality of partial remaining power levels P_REM _{PER2_1} to P_REM _{PER2 _m} are stored, so that storage space for calculating the remaining power level P_REM _PER2 can be saved. For example, when the second period PER2 has a length corresponding to 300,000 transmission units and the plurality of sub-periods SP_1 to SP_m have the same length corresponding to 1,000 transmission units (ie, when 'm' is 300 in FIG. 4), the remaining power calculator 1320 of FIG. 1 may know 300 partial remaining power levels instead of storing 300,000 remaining power levels. .

5 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure. As shown in FIG. 5, the user device 1000a may include an antenna 1100a, a transceiver module 1200a, and a transmission power controller 1300a, and may further include an antenna 1400a, a wireless communication module 1500a, a sensor subsystem 1600a, and a beamforming controller 1700a compared to the user device 1000 of FIG. In the following description of FIG. 5 , contents overlapping with the description of FIG. 1 will be omitted.

According to an exemplary embodiment of the present disclosure, the remaining power level P_REM may be calculated based on the status of the user equipment 1000a. For example, as shown in FIG. 5, the remaining power calculator 1320a of the transmission power controller 1300a may receive a state signal S_STA including information about the state of the user device, and calculate the remaining power level P_REM based on the state signal S_STA. As described above, since the SAR for the user of the user device 1000a may be determined according to various factors, transmission power may be optimally controlled by reflecting the state of the user device 1000a in the remaining power level P_REM.

The wireless communication module 1500a may communicate with the wireless communication device 3000 through a wireless communication channel 30 formed in a wireless communication method different from that of the downlink 10 and the uplink 20 . For example, the wireless communication channel 30 may be formed by a wireless communication method such as WiFi (Wireless Fidelity), WiBro (Wireless Broadband Internet), WIMAX (World Interoperability for Microwave Access), Zigbee, Bluetooth, etc., as non-limiting examples. In addition, as a non-limiting example, the wireless communication device 3000 may be an Access Pint (AP), a wearable computer, an earphone, a headset, and the like. RF signals output through the antenna 1400a to communicate with the wireless communication device 3000 may also contribute to energy radiated from the user device 1000a, and thus affect the body absorption rate (SAR). Accordingly, the status signal S_STA may include channel information I_CHA about the wireless communication channel 30 .

The sensor subsystem 1600a may include at least one sensor that detects a state of the user device 1000a that affects a specific absorption rate (SAR). In one embodiment, the sensor subsystem 1600a may include a tilt sensor that detects a tilt of the user device 1000a. When a user uses the user device 1000a to communicate with the base station 2000, the tilt of the user device 1000a is likely to be within a certain range. Accordingly, the state signal S_STA may include the tilt information I_ANG generated by the tilt sensor.

In one embodiment, sensor subsystem 1600a may include a grip sensor. The grip sensor may detect whether or not the user is in contact with the user device 1000a or whether or not the user is holding the user device 1000a. Since the user and the user device 1000a are in contact and the wider the contact area, the SAR may increase, so the status signal S_STA may include the contact information I_CON generated by the grip sensor.

In one embodiment, sensor subsystem 1600a may include a proximity sensor. The proximity sensor may detect a distance between the user and the user device 1000a. Since SAR increases as the distance between the user and the user device 1000a decreases, the state signal S_STA may include distance information I_DIS generated by the proximity sensor. Also, the proximity sensor may detect the user's direction to the user device 1000a. When the antenna 1100a and the transceiver module 1200a of the user device 1000a perform directional transmission in which signals are transmitted toward the location of the base station 2000, the SAR may increase as the direction of the user to the user device 1000a and the direction of the base station 2000 are similar. Accordingly, the state signal S_STA may include the user's direction information I_DIR generated by the proximity sensor.

The beamforming controller 1700a may control an antenna beam formed by the antenna 1100a. As shown in FIG. 5 , the beamforming controller 1700a may output a beamforming control signal C_BF, and the transceiver module 1200a may form an antenna beam in the antenna 1100a based on the beamforming control signal C_BF. As described above, since the shape of the beam formed by the antenna 1100a and the direction of the user may affect the SAR, the state signal S_STA may include beamforming information I_BF related to beamforming generated by the beamforming controller 1700a.

According to an exemplary embodiment of the present disclosure, the status signal S_STA may include all or part of the above-described various information. Accordingly, the remaining power calculator 1320a may calculate the remaining power level P_REM based on at least some of a plurality of pieces of information representing the state of the user device 1000a.

6 is a flow chart illustrating an example operation of the remaining power calculator 1320a of FIG. 5 according to an exemplary embodiment of the present disclosure. As shown in FIG. 6 , the remaining power calculator 1320a may calculate the remaining power level P_REM by adjusting the allowable power level P_TOT and/or the transmission power level P_TX based on the state of the user equipment 1000a. Referring to FIG. 6 , state information D22 including distance information (I_DIS), contact information (I_CON), direction information (I_DIR), beamforming information (I_BF), tilt information (I_ANG), and channel information (I_CHA) may be used.

In step S21, an operation of calculating a first weight W ₁ and a second weight W ₂ based on the state information D22 may be performed. The first weight W ₁ may be used to adjust the allowable power level P_TOT, and the second weight W ₂ may be used to adjust the transmit power level P_TX. As shown in FIG. 6, the first weight W ₁ may be calculated by a first function g 1 having state information D22 as a parameter, and the second weight _{W 2 may} be calculated by a second function g ₂ taking state information D22 as a parameter.

The first function g ₁ may output a first weight value W ₁ having a relatively small value so that the adjusted allowable power level P_TOT _ADJ decreases when it is necessary to increase the SAR by the user device 1000a according to the state information D22. In addition, the first function (g ₁ ) may output a first weight (W ₁ ) having a relatively large value so that the adjusted allowable power level (P_TOT _ADJ ) rises when it is necessary to lower the SAR by the user device (1000a) according to the state information (D22). For example, the first weight W ₁ may be proportional to the distance indicated by the distance information I_DIS and inversely proportional to the contact area indicated by the contact information I_CON, by the first function g ₁ . In addition, the first weight W ₁ may be in inverse proportion to the correlation between the direction indicated by the user's direction information I_DIR and the beamforming information I_BF, and may be inversely proportional to the correlation between the slope indicated by the tilt information I_ANG and the tilt of the user device 1000a when the user uses it, by the first function g ₁ . In addition, when the _{communication channel indicated by the channel information I_CHA is activated by the first function g 1 ,} the first weight value W ₁ having a relatively small value may be output.

On the other hand, the second function ( _g2 ), when it is necessary to increase the SAR by the user device 1000a according to the state information (D22), can output a second weight ( _W2 ) having a relatively large value so that the adjusted transmit power level (P_TX _ADJ ) rises. In addition, the second function _g2 may output a second weight _W2 having a relatively small value so that the adjusted transmission power level P_TX _ADJ decreases when it is necessary to adjust the SAR by the user device 1000a downward according to the state information D22. For example, the second weight W ₂ may be inversely proportional to the distance indicated by the distance information I_DIS and may be proportional to the contact area indicated by the contact information I_CON by the second function g ₂ . In addition, the second weight W ₂ may be proportional to the correlation between the direction indicated by the direction information I_DIR of the user and the beamforming information I_BF, and may be proportional to the correlation between the slope indicated by the tilt information I_ANG and the tilt of the user device 1000a when the user uses the first function (g ₂ ). In addition, when _{the communication channel indicated by the channel information (I_CHA) is activated by the second function (g 2 )} , the second weight value (W ₂ ) having a relatively small value may be output.

In step S22, an operation of calculating an adjusted allowable power level (P_TOT ADJ) using a first weight (W ₁ ) and calculating an adjusted transmit power level (P_TX _ADJ ) using a second weight (W ₂ ) from the allowable power level (P_TOT) and the power _level (P_TX) may be performed. Based on the values of the first and second weights W ₁ and W ₂ calculated in step S21, the adjusted allowable power level P_TOT _ADJ and the adjusted transmit power level P_TX _ADJ may reflect the state of the user equipment 1000a.

In step S23, an operation of calculating remaining power levels P_REM _PER2 and P_REM _PER3 based on the adjusted allowable power level P_TOT _ADJ and the adjusted transmit power level P_TX _ADJ may be performed. Accordingly, the remaining power levels P_REM _PER2 and P_REM _PER3 reflecting various factors of the SAR may be calculated, and the remaining power level P_REM _PER3 of the third period PER3 may be output.

7 is a block diagram illustrating an example 1340′ of the transmit power calculator 1340 of FIG. 1 according to an exemplary embodiment of the present disclosure, and FIG. 8 is a flowchart illustrating the operation of the transmit power calculator 1340′ of FIG. 7 according to an exemplary embodiment of the present disclosure. As described above with reference to FIG. 1, the transmit power calculator 1340′ may receive the requested power level P_REQ from the transceiver module 1200 of FIG. 1, receive the remaining power level P_REM from the remaining power calculator 1320 of FIG.

Referring to FIG. 7 , the transmit power calculator 1340′ may include a plurality of reference levels P_REF ₁ to P_REF _k and a plurality of limit levels P_LIM ₁ to P_LIM _k respectively corresponding to the plurality of reference levels P_REF ₁ to P_REF _k . For example, the transmit power calculator 1340′ may include a storage space for storing a plurality of reference levels P_REF ₁ to P_REF _k and a plurality of limit levels P_LIM ₁ to P_LIM _k , such as a memory or a register. As will be described later with reference to FIG. 8, the transmit power calculator 1340′ may compare the remaining power level P_REM with at least one of a plurality of reference levels P_REF ₁ to P_REF _k , and determine the transmit power level P_TX based on the comparison result. That is, the transmit power calculator 1340 ′ may limit the transmit power level P_TX as one of a plurality of limit levels P_REM ₁ to P_LIM _k according to the comparison result.

Referring to FIG. 8 , in step S41, an operation of setting a target power level P_TAR based on the requested power level P_REQ may be performed. The target power level P_TAR may be set to the requested power level P_REQ, which is the transmission power level requested by the base station 2000 of FIG. 1, or may be set to the dummy power level P_DUM. Details of step S46 will be described later with reference to FIGS. 12 and 13 .

In steps S42_1 to S42_k, an operation of comparing the remaining power level P_REM and the plurality of reference levels P_REF ₁ to P_REF _k may be performed. For example, according to the comparison result of the step (S42_j) of comparing the remaining power level (P_REM) and the reference level (P_REF _j ), whether to perform the step (S42_j+ ₁ ) of comparing the remaining power level (P_REM) and the reference level (P_REF _{j +} 1) may be determined. That is, the remaining power level P_REM may be compared with at least one of a plurality of reference levels P_REF ₁ to P_REF _k . The plurality of reference levels P_REF ₁ to P_REF _k may be arranged in ascending order (ie, P_REF _j < P_REF _j+1 ).

According to a result of comparing the remaining power level P_REM and at least one of the plurality of reference levels P_REF ₁ to P_REF _k , an operation of setting the maximum power level P_MAX to one of the plurality of limit levels P_LIM ₁ to P_LIM _k or to the default power level P_DEF may be performed in steps S43_0 to S43_k. For example, in step S42_j, when the remaining power level P_REM is less than the reference level P_REF _j , the maximum power level P_MAX may be set as the limit level P_LIM _j . When the remaining power level (P_REM) is greater than or equal to the largest reference level (P_REF _k ) among the plurality of reference levels (P_REF ₁ to P_REF _k ) by the comparison operation of step S42_k, the maximum power level (P_MAX) can be set as the default power level (P_DEF). A plurality of threshold levels (P_LIM ₁ to P_LIM _k ) may be arranged in ascending order (ie, P_LIM _j ≤ P_LIM _{j +1} ). That is, as the remaining power level P_REM is smaller, the maximum power level P_MAX may be smaller.

In step S44, the transmission power level (P_TX) may be set to a smaller value among the target power level (P_TAR) and the maximum power level (P_MAX). That is, the transmit power level (P_TX) is set to the target power level (P_TAR) (not related to the SAR), but may be limited to the maximum power level (P_MAX) (related to the SAR).

9 is a block diagram illustrating an example 1340″ of the transmit power calculator 1340 of FIG. 1 according to an exemplary embodiment of the present disclosure, and FIG. 10 is a flowchart illustrating the operation of the transmit power calculator 1340″ of FIG. 9 according to an exemplary embodiment of the present disclosure.

Referring to FIG. 9, the transmit power calculator 1340″ may include a plurality of reference levels P_REF′ ₁ to P_REF′ _k and a plurality of backoff levels B_LEV _{1 to B_LEV k respectively corresponding to the plurality of reference levels P_REF′ 1 to P_REF} ′ _k . For example, the transmit power calculator 1340″ may include a storage space for storing a plurality of reference levels (P_REF′ ₁ to P_REF′ _k ) and a plurality of backoff levels (B_LEV ₁ to B_LEV _k ) such as a memory or a register. As will be described later with reference to FIG. 10, the transmit power calculator 1340″ may compare the remaining power level P_REM with at least one of a plurality of reference levels _{P_REF′1} to _{P_REF′k} , and determine the transmit power level P_TX based on the comparison result. That is, the transmit power calculator 1340 ″ may decrease the target transmit power P_TAR by one of a plurality of backoff levels B_LEV ₁ to B_LEV _k according to the comparison result.

Referring to FIG. 10 , in step S45, an operation of setting a target power level P_TAR based on the requested power level P_REQ may be performed. Then, in steps S46_1 to S46_k, an operation of comparing the remaining power level P_REM and the plurality of reference levels P_REF' ₁ to P_REF' _k , respectively, may be performed. For example, according to the comparison result of the step S46_j of comparing the remaining power level P_REM and the reference level P_REF' _j , whether to perform the step S46_j+ ₁ of comparing the remaining power level P_REM and the reference level P_REF' _{j +} 1 may be determined. That is, the remaining power level P_REM may be compared with at least one of a plurality of reference levels P_REF' ₁ to P_REF' _k . The plurality of reference levels P_REF' ₁ to P_REF' _k may be arranged in ascending order (ie, P_REF' _j <P_REF' _j+1 ).

According to a result of comparing the remaining power level P_REM and at least one of the plurality of reference levels P_REF' ₁ to P_REF' _k , an operation of setting the final back-off level B_FIN to one of the plurality of back-off levels B_LEV ₁ to B_LEV _k or the default back-off level B_DEF may be performed in steps S47_0 to S47_k. For example, when the remaining power level (P_REM) is less than the reference level (P_REF' _j ) in step S46_j, the final back-off level (B_FIN) may be set to the back-off level (B_LEV _j ). According to the comparison operation of step S46_k, when the remaining power level P_REM is greater than or equal to the largest reference level P_REF _k among the plurality of reference levels P_REF ₁ to P_REF _k , the final back-off level B_FIN can be set as the default back-off level B_DEF. A plurality of threshold levels (P_LIM ₁ to P_LIM _k ) may be arranged in descending order (ie, P_LIM _j ≥ P_LIM _{j +1} ). That is, as the remaining power level P_REM is smaller, the final backoff level B_FIN may be larger.

In step S48, an operation of comparing the target power level (P_TAR) and the default power level (P_DEF') may be performed. When the target power level P_TAR is smaller than the default power level P_DEF', an operation of setting the transmission power level P_TX to the target power level P_TAR may be performed in step S49_1. On the other hand, when the target power level P_TAR is equal to or greater than the default power level P_DEF', the transmission power level P_TX may be set as a difference between the target power level P_TAR and the final backoff level B_FIN in step S49_2.

11 is a graph illustrating a change in the remaining power level (P_REM) over time according to an exemplary embodiment of the present disclosure. As described above with reference to FIGS. 7 to 10 , the remaining power level P_REM may be compared with at least one of a plurality of reference levels P_REF ₁ to P_REF _k . In the following, FIG. 11 will be described with reference to FIG. 8 .

Referring to FIG. 11, due to the requested power level (P_REQ) having a high value (e.g., when the uplink 20 of FIG. 1 is not good), when wireless transmission continuously proceeds with a high transmit power level (P_TX), the remaining power level (P_REM) may gradually decrease over time from the allowed power level (P_TOT) as shown in FIG. At a point in time when the remaining power level (P_REM) is less than the reference level (P_REF _k ), the transmit power level (P_TX) may be limited by the limit level (P_LIM _k ). In this way, when the remaining power level P_REM continuously decreases, the transmit power level P_TX may sequentially cross the reference levels P_REF _k to P_REF ₁ . The transmission power level P_TX is limited according to the limit levels P_LIM _k to P_LIM ₁ corresponding to the reference levels P_REF _k to P_REF ₁ , and accordingly, as shown in FIG. 11, the remaining power level P_REM may gradually decrease below the highest reference level P_REF _k .

12 is a flowchart illustrating a method of setting a target power level (P_TAR) according to an exemplary embodiment of the present disclosure, and FIG. 13 is a diagram showing the remaining power level (P_REM _PER2 ) of a second period (PER2) including periods without radio transmission according to an exemplary embodiment of the present disclosure. Specifically, FIG. 12 may show an example of step S41 of FIG. 8 or step S45 of FIG. 10 performed by the transmit power calculator 1340 of FIG. 1 . 12 and 13 will be described with reference to FIG. 1 below.

Referring to FIG. 12 , in step S41_1, an operation of determining whether or not it is a period without radio transmission may be performed. For example, in LTE, the user equipment 1000 may be in an RRC_CONNECTED state or an RRC_IDLE state. The RRC_CONNECTED state may be a state in which an 'RRC context' is formed, that is, a state in which parameters necessary for the user device 1000 and the base station 20000 to communicate with each other are known to both sides. In the RRC_CONNECTED state, the user device 1000 may set Discontinuous Reception (DRX) to reduce power consumption. In addition, the user device 1000 may set discontinuous transmission (DTX) by shutting off or muting wireless transmission, for example, while the user's voice input is not sufficient. Meanwhile, in the RRC_IDLE state, the user device 1000 may not belong to a specific cell without 'RRC context'. For the purpose of reducing power consumption, the user equipment 1000 may sleep for most of the time in the RRC_IDLE state, and thus radio transmission may not occur. The transmission power calculator 1340 may set the target power level P_TAR differently by determining whether the user equipment 1000 is in a period without such wireless transmission. That is, the transmission power calculator 1340 may calculate the transmission power level (P_TX) by generating the target power level (P_TAR) even in a period without wireless transmission, and the remaining power level (P_REM _PER2 ) of the second period (PER2) may be updated by the calculated transmission power level (P_TX). Accordingly, energy emitted by the user device 1000 can be managed regardless of whether or not wireless transmission is performed during a certain period (eg, the first period PER1 of FIG. 2 ).

In the case of a period without wireless transmission, the target power level P_TAR may be set to the dummy power level P_DUM in step S41_2. Otherwise, the target power level P_TAR may be set to the requested power level P_REQ in step S41_3. That is, in a period without wireless transmission, the transmit power level may be set to a dummy power level (P_DUM) having a predetermined value. The dummy power level P_DUM may have any predetermined size, and may be, for example, a minimum power level or zero.

Referring to FIG. 13 , the transmit power level P_TX may be the dummy power level P_DUM in periods P1 and P2 without radio transmission. As described above with reference to FIG. 12 , the periods P1 and P2 without radio transmission may be DRX, DTX, or a period in which the user equipment 1000 is in a sleep state. In the periods P1 and P2 without radio transmission, the target power level P_TAR may be set to the dummy power level P_DUM, and when the dummy power level P_DUM has zero or a value representing the minimum power level, as shown in FIG. 13 , the transmission power level P_TX may be equal to the dummy power level P_DUM regardless of the remaining power level P_REM. The remaining power level P_REM _PER2 of the second period PER2 may accumulate differences between the average power level P_AVG and the dummy power level P_DUM in periods P1 and P2 without radio transmission.

14 illustrates examples of controlling transmission power of a transmission unit over time according to an exemplary embodiment of the present disclosure. Specifically, FIG. 14 shows an exemplary operation of the control signal generator 1360 of FIG. 1, and as described above with reference to FIG. 1, the control signal generator 1360 receives from the transmit power calculator 1340. Based on the transmit power level (P_TX), the power control signal (C_POW) can be generated. The power control signal C_POW may determine the power level (TX Power) of the transmission unit (TX Unit). Hereinafter, FIG. 14 will be described with reference to FIG. 1 .

According to an exemplary embodiment of the present disclosure, the transmit power level (P_TX) received by the control signal generator 1360 may correspond to a series of transmission units. For example, as shown in FIG. 14 , the transmit power level P_TX generated by the transmit power calculator 1340 may correspond to 20 transmit units. The transmit power level (P_TX) may correspond to the average transmit power of 20 transmission units or may correspond to the total transmit power of 20 transmission units. That is, the level indicated by the dotted line in FIG. 14 may be the transmit power level (P_TX) or may be a level obtained by dividing the transmit power level (P_TX) by 20, which is the number of transmission units. Hereinafter, the level indicated by the dotted line in FIG. 14 is assumed to be the transmit power level (P_TX).

The control signal generator 1360 may generate the power control signal C_POW so that the plurality of transmission units satisfy the transmission power level P_TX. For example, as shown in (a) of FIG. 14, the control signal generator 1360 may generate the power control signal C_POW such that the power level (TX Power) of each transmission unit is less than or equal to the transmission power level (P_TX). In addition, as shown in (b) to (d) of FIG. 14, the control signal generator 1360 may generate the control signal C_POW such that the total power level of the two transmission units satisfies the transmission power level P_TX. Also, the control signal generator 1360 may generate the power control signal C_POW such that the power level of the transmission unit is equal to or higher than the minimum power level P_MIN for maintaining the connection with the base station 2000 . For example, as shown in FIG. 14 , the transmission unit may have a power level higher than the lowest power level (P_MIN) by the control signal generator 1360 .

15 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure. As shown in FIG. 15, the user device 1000b may further include an antenna 1100b, a transceiver module 1200b, a transmit power controller 1300b, an antenna 1400b, a wireless communication module 1500b, a sensor subsystem 1600b, and a beamforming controller 1700b. Compared to the user device 1000a of FIG. 5 , the sensor subsystem 1600b may output a direction signal S_DIR to the beamforming controller 1700b. Among the descriptions of FIG. 15 below, descriptions overlapping those of FIG. 5 will be omitted.

According to an exemplary embodiment of the present disclosure, the user device 1000b may deform the beam to reduce the body absorption rate (SAR) of radio transmission. As shown in FIG. 15 , the sensor subsystem 1600b may include a proximity sensor that detects the user's direction with respect to the user device 1000a, and may output a direction signal S_DIR generated by the proximity sensor and including information on the user's direction I_DIR to the beamforming controller 1700b. The beamforming controller 1700b may output a beamforming control signal C_BF in response to the direction signal S_DIR to change the shape (eg, direction and/or shape of the beam) of the beam formed in the antenna 1100b. That is, the beamforming controller 1700a may generate the beamforming control signal C_BF so that the correlation between the user's direction and beamforming decreases. For example, the beam forming controller 1700b may change the shape of the beam so that the overlapping portion of the beam formed around the antenna 1200b and the direction of the user is reduced.

16 is a flowchart illustrating a method for controlling transmission power in a wireless communication device according to an exemplary embodiment of the present disclosure. The transmission power control method may be performed by a transmission power control device, for example, the transmission power controller 1300 of FIG. 1 . Hereinafter, FIG. 16 will be described with reference to FIG. 1 .

In step S100, an operation of calculating the remaining power level (P_REM) based on the allowable power level (P_TOT) and the transmission power level (P_TX) may be performed. For example, referring to FIGS. 3A and 3B , the remaining power calculator 1320 of the transmission power controller 1300 may calculate the remaining power level P_REM PER2 of the second period PER2 from the present to the past based on the allowable power level P_TOT _PER1 of the first period PER1 and the transmit power level P_TX, and calculate the allowable power level P_TOT of the third period _{PER3 from the present to the future. The remaining power level P_REM PER3 of} the third period PER3 may be calculated by reflecting the remaining power level _{P_REMPER2} of the second period PER2 in PER3 . The allowable power level (P_TOT _PER1 ) of the first period (PER1) may be determined by the allowable electromagnetic wave absorption rate (SAR _limit ), and the remaining power level (P_REM _PER2 ) may be calculated from the transmit power levels of the second period (PER2).

In step S300, based on the remaining power level (P_REM) and the target power level (P_TAR), an operation of calculating the transmission power level (P_TX) may be performed. For example, the transmit power calculator 1340 of the transmit power controller 1300 may set the target power level P_TAR based on the requested power level P_REQ, and may determine the transmit power level P_TX as the target power level P_TAR or as a level lower than the target power level P_TAR according to the remaining power level P_REM.

In step S500, an operation of generating a power control signal C_POW based on the transmit power level P_TX may be performed. For example, the power control signal C_POW may determine the power level of the transmission unit. The control signal generator 1360 of the transmit power controller 1300 generates the control signal C_POW according to the transmit power level P_TX when the transmit power level P_TX corresponds to one transmit unit, while when the transmit power level P_TX corresponds to a series of transmit units, the control signal generator 1360 may sequentially generate a series of power control signals C_POW based on the transmit power level P_TX.

17 is a flowchart illustrating a method of calculating a remaining power level (P_REM) according to an exemplary embodiment of the present disclosure. The method of FIG. 17 may represent an example of step S100 of FIG. 16 and may be performed by the remaining power calculator 1320a included in the transmission power controller 1300a of FIG. 5 . Since the SAR for the user of the user device 1000a may be determined according to various factors, the state of the user device 1000a may be considered when calculating the remaining power level P_REM to reflect this. Hereinafter, FIG. 17 will be described with reference to FIG. 5 .

In step S110, an operation of receiving the status signal S_STA may be performed. The state signal S_STA may include at least one of state information of the user device 1000a, for example, distance information (I_DIS), contact information (I_CON), direction information (I_DIR), beamforming information (I_BF), tilt information (I_ANG), and channel information (I_CHA).

In step S130, an operation of adjusting the allowable power level P_TOT and/or the transmission power level P_TX may be performed based on the information included in the state signal S_STA. In order to increase or decrease the SAR by the user device 1000a according to the state information included in the state signal S_STA, the allowed power level P_TOT and/or the transmit power level P_TX may be adjusted to generate the adjusted allowable power level P_TOT _ADJ and/or the adjusted transmit power level P_ACC _ADJ .

In step S150 , an operation of calculating a remaining power level based on the adjusted allowable power level (P_TOT _ADJ ) and/or the adjusted transmit power level (P_TX _ADJ ) may be performed. That is, the remaining power level P_REM PER2 of the second period PER2 may be calculated based on the adjusted allowable power level P_TOT _ADJ and/or the adjusted transmit power level P_TX _ADJ , and the remaining power level P_REM _PER3 of the third period _PER3 may be calculated based on the remaining power level P_REM _PER2 of the second period PER2. As the state of the user device 1000a is reflected, as a result, the remaining power levels P_REM _PER2 and P_REM _PER3 may have more realistic values in order for the user device 1000a to satisfy the allowable electromagnetic wave absorption rate (SARlimit).

18 is a flowchart illustrating a method of calculating a transmit power level (P_TX) according to an exemplary embodiment of the present disclosure. Specifically, the method of FIG. 16 may represent an example of step S300 of FIG. 16 and may be performed by the transmission power calculator 1340 included in the transmission power controller 1300 of FIG. 1 . 18 will be described with reference to FIGS. 7 and 8 showing the transmission power calculator 1340' and its operation.

In step S310, an operation of comparing the remaining power level P_REM with at least one reference level among a plurality of reference levels may be performed. For example, the remaining power level P_REM may be compared with at least one of a plurality of reference levels P_REF ₁ to P_REF _k included in the transmit power calculator 1340' of FIG. 7 . The plurality of reference levels P_REF ₁ to P_REF _k may be arranged in ascending order, and the remaining power level P_REM may be sequentially compared from the reference level P_REF ₁ having the smallest value to the reference level P_REF _k having the highest value.

In step S330, an operation of determining a transmit power level (P_TX) based on the comparison result may be performed. For example, when the remaining power level (P_REM) is smaller than a specific reference level (P_REF _j ), the transmit power level (P_TX) may be limited to a limit level (P_LIM _j) or less corresponding to the reference level (P_REF _j ) among a plurality of limit levels (P_LIM ₁ to P_LIM _k ) included in the transmit power calculator 1340' of FIG. That is, the transmit power level (P_TX) may be appropriately limited based on the size of the remaining power level (P_REM).

19 is a graph illustrating an example in which transmission power is controlled according to a transmission power control method according to an exemplary embodiment of the present disclosure. Referring to FIG. 19, in t1 to t2, the power level (TX Power) of the transmission unit also has a high value according to the requested power level (P_REQ) of a high value, and the average of the power level (TX Power) of the transmission unit may rise. From t2 to t3, as the average of the transmission power levels (P_TX) approaches the allowable electromagnetic wave absorption rate (SARlimit), the power level (TX Power) of the transmission unit may be limited to a level lower than the requested power level (P_REQ), and accordingly, the average power level (TX Power) of the transmission unit may rise more gently than before. As shown in FIG. 19 , the power level (TX Power) of the transmission unit may decrease step by step, and the average of the power level (TX Power) of the transmission unit may be controlled to be less than the allowable electromagnetic wave absorption rate (SAR _limit ).

20 is a block diagram illustrating an example of a wireless communication system using a transmission power control method according to an exemplary embodiment of the present disclosure. As shown in FIG. 20 , a user equipment 1000c may include an antenna 1100c, a transceiver module 1200c, and a transmission power controller 1300c. Compared to the transmission power controller 1300 of FIG. 1 , the transmission power controller 1300c of FIG. 20 may include a residual energy calculator 1320c. Among the descriptions of FIG. 20 below, descriptions overlapping those of FIG. 1 will be omitted.

According to an exemplary embodiment of the present disclosure, the transmit power controller 1300c may calculate the remaining radiated energy (E_REM) based on the allowable radiated energy (E_TOT) and the energy used for wireless transmission, and may calculate the transmit power level (P_TX) based on the remaining radiated energy (E_REM). Since the SAR by the user device 1000c is due to the energy radiated from the user device 1000c, the transmit power controller 1300c may estimate the used energy radiated from the user device 1000c based on the transmit power used for wireless transmission, and calculate the allowable radiated energy E_TOT determined according to the allowable value of the SAR and the remaining radiated energy E_REM based on the used energy. You can.

Referring to FIG. 20 , the remaining energy calculator 1320c may include allowable radiant energy E_TOT, and may calculate and output the remaining radiant energy E_REM. The remaining energy calculator 1320c may calculate used energy from the transmit power level P_TX received from the transmit power calculator 1340c. Similar to the above with reference to FIGS. 3A and 3B , the allowable radiated energy E_TOT may correspond to the radiated energy for the user device 1000c to comply with the allowable value of the SAR during the first period PER1, and the used radiated energy may correspond to the energy radiated from the user device 1000c in the second period PER2 from the transmission power level of the second period PER2. In addition, the remaining radiant energy E_REM may correspond to energy that can be radiated by the user device 1000c while complying with the allowable value of the SAR for the third period PER3.

21 shows an exemplary block diagram of a wireless communication device 4000 according to an exemplary embodiment of the present disclosure. As shown in FIG. 21, the wireless communication device 4000 may include an Application Specific Integrated Circuit (ASIC) 4100, an Application Specific Instruction set Processor (ASIP) 4300, a memory 4500, a main processor 4700, and a main memory 4900. Two or more of ASIC 4100, ASIP 4300 and main processor 4700 may communicate with each other. Also, at least two or more of the ASIC 4100, the ASIP 4300, the memory 4500, the main processor 4700, and the main memory 4900 may be embedded in one chip.

The ASIC 4100 is an integrated circuit customized for a specific purpose, and may include, for example, an RFIC, a modulator, a demodulator, and the like. The ASIP 4300 may support a dedicated instruction set for a specific application, and may execute instructions included in the instruction set. The memory 4500 may communicate with the ASIP 4300 and may store a plurality of instructions executed by the ASIP 4300 as a non-temporary storage device. For example, memory 4500 may include any type of memory accessible by ASIP 4300, such as random access memory (RAM), read only memory (ROM), tape, magnetic disk, optical disk, volatile memory, non-volatile memory, and combinations thereof.

The main processor 4700 may control the user device 4000 by executing a plurality of instructions. For example, the main processor 4700 may control the ASIC 4100 and the ASIP 4300, process data received through a wireless communication network, or process a user's input to the user device 4000. The main memory 4900 may communicate with the main processor 4700 and may store a plurality of instructions executed by the main processor 4900 as a non-temporary storage device. For example, main memory 4900 may include any type of memory accessible by main processor 4700, such as random access memory (RAM), read only memory (ROM), tape, magnetic disk, optical disk, volatile memory, non-volatile memory, and combinations thereof.

The step of configuring the components of the wireless communication device (e.g., the user device 1000 of FIG. 1) or the method for controlling transmission power according to the exemplary embodiment of the present disclosure described above is the wireless communication device of FIG. 21. At least one of the components included in the 4000 may be included. For example, at least one of the steps of the transmission power controller 1300 of FIG. 1 or the transmission power control method described above may be implemented as a plurality of instructions stored in the memory 4500, and the ASIP 4300 may perform the operation of the transmission power controller 1300 or at least one step by executing a plurality of instructions stored in the memory 4500. As another example, at least one step of the transmit power controller 1300 of FIG. 1 or the transmit power control method described above may be implemented as a hardware block and included in the ASIC 4100. As another example, at least one of the steps of the transmit power controller 1300 of FIG. 1 or the transmit power control method described above may be implemented as a plurality of instructions stored in the main memory 4900, and the main processor 4700 may perform an operation of the transmit power controller 1300 or at least one step by executing a plurality of instructions stored in the main memory 4900.

As above, exemplary embodiments have been disclosed in the drawings and specifications. Embodiments have been described using specific terms in this specification, but they are only used for the purpose of explaining the technical idea of the present disclosure, and are not used to limit the scope of the present disclosure described in the meaning or claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present disclosure should be determined by the technical spirit of the appended claims.

Claims (10)

A method for controlling transmission power used for wireless transmission in a wireless communication device,
calculating a remaining power level of a third period included in the first period and future from the present, based on the allowable power level of the first period and the remaining power level of a second period from now to the past;
calculating a transmission power level in the third period based on the remaining power level and the target power level in the third period; and
and generating a power control signal for determining a power level of a transmission signal unit based on the transmission power level of the third period. According to claim 1,
The first period is equal to the sum of the second period and the third period,
Wherein the step of calculating the remaining power level of the third period calculates the allowed power level of the third period from the allowed power level of the first period, and calculates the remaining power level of the third period by adding the remaining power level of the second period to the allowed power level of the third period. According to claim 1,
The first period is less than the sum of the second period and the third period,
The step of calculating the remaining power level of the third period includes calculating the allowed power level of the third period from the allowed power level of the first period, and calculating the remaining power level of the third period such that the remaining power level of the third period is a weighted sum of the allowed power level of the third period and the remaining power level of the second period. According to claim 1,
and calculating a remaining power level in the second period based on the allowable power level in the first period and the transmission power level in the second period. According to claim 4,
The second period includes a plurality of sub-periods corresponding to two or more transmission signal units,
The calculating of the remaining power level of the second period comprises calculating the remaining power level of the second period based on a plurality of partial remaining power levels corresponding to the plurality of sub-periods. Transmission power control method. According to claim 4,
The transmission power control method,
receiving a status signal generated within the wireless communication device and indicative of a status of the wireless communication device; and
Adjusting the allowable power level of the first period or the transmit power level of the second period based on the status signal;
The step of calculating the remaining power level of the second period and the step of calculating the remaining power level of the third period calculate the remaining power level of the second period and the remaining power level of the third period based on the adjusted allowable power level of the first period or the adjusted transmit power level of the second period, respectively. According to claim 1,
Calculating the transmit power level of the third period includes:
comparing the remaining power level of the third period with at least one reference level among a plurality of reference levels; and
and determining a transmission power level in the third period based on a comparison result. According to claim 1,
Generating the power control signal generates the power control signal such that a total power level used in a series of transmission signal units during the third period is equal to or less than the transmission power level of the third period. Transmit power control method, characterized in that for generating. According to claim 1,
The transmit power control method according to claim 1 , wherein the allowable power level of the first period is determined based on a limit of a specific absorption rate (SAR). According to claim 1,
further comprising setting the target power level based on a command received by the wireless communication device;
Wherein the step of setting the target power level sets the target power level to a predetermined dummy power level in a period without wireless transmission.

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