Patent Description:
In a process of transmitting radio waves from an electronic device to a base station, when the transmission power of the electronic device exceeds a certain strength, the electronic device may affect the health of a human body. Therefore, a transmission function of the electronic device needs to comply with relevant regulations of SAR (Specific Absorption Rate).

In order to ensure that the transmission power complies with a SAR requirement, a solution of time-averaged SAR is provided in the related art. The electronic device may transmit at full power Pmax in a time period during of a preset time window (ICNIRP and FCC use different time windows, taking a frequency band of sub6G as an example, ICNIRP sets <NUM>, FCC sets <NUM>), and transmit at lower power in the remaining time period of the preset time window, and ensure that an average power in the time window is not greater than Plimit. Plimit refers to a fixed upper limit value of power.

However, in the solution provided by the related art, it is required a long time interval to transmit at a higher power. For continuous service scenarios such as games or calls, uplink signals may deteriorate during this period, and use experience may be reduced.

<CIT> provides an electronic device and method for controlling the same. An electronic device includes: an antenna; a communication circuit connected with the antenna; and one or more processors, wherein the one or more processors are configured to: identify a second amount of power corresponding to a second output signal outputted through the antenna for a second time using the communication circuit, the operation of identifying the second amount of power comprising an operation of identifying a second electromagnetic wave absorption rate corresponding to the second amount of power; determine a maximum output power for a third output signal to be outputted through the antenna according to a difference between a target electromagnetic wave absorption rate and the second electromagnetic absorption rate; and output the third output signal through the antenna based at least one the maximum output power.

The present invention provides a method and an apparatus for controlling a transmission power, and a storage medium.

According to a first aspect of embodiments of the present invention, a method for controlling a transmission power as defined in claim <NUM> is provided. The method includes determining a target number of transmission cycles according to a service scenario of an electronic device, in which a preset time window is divided into the target number of transmission cycles, and the preset time window is a test cycle used in a specific absorption rate (SAR) test of the electronic device. The method further includes determining at least one of an upper limit value or a lower limit value of a transmission power corresponding to each transmission cycle, in which an average value of transmission powers in the preset time window complies with a SAR requirement, and controlling the electronic device to transmit and receive signals using a corresponding transmission power in each transmission cycle.

Determining, according to the service scenario of the electronic device, the target number of transmission cycles into which the preset time window is divided incudes: the greater a number of continuous and real-time services included in the service scenario, the greater a value of the target number; or the greater a number of non-continuous services and non-real-time services included in the service scenario, the smaller the value of the target number.

In embodiments, determining the target number of transmission cycles according to the service scenario of the electronic device includes: in a first service scenario, determining that the target number of the transmission cycles is a first number, wherein, in the first service scenario, each service of the electronic device is of a non-continuous type or a non-real-time type; or, in a second service scenario, determining that the target number of the transmission cycles is a second number, wherein, in the second service scenario, each service of the electronic device is of a continuous and real-time type; or, in a third service scenario, determining that the target number of the transmission cycles is a third number, wherein in the third service scenario, each service of the electronic device is of the continuous and real-time type, or the non-continuous type, or the non-real-time type; in which, the first number is less than the third number, and the third number is less than the second number.

In embodiments, determining the upper limit value of the transmission power corresponding to each transmission cycle includes: determining an upper limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and determining the upper limit value of the transmission power corresponding to each transmission cycle by obtaining a sum of a limited power under the SAR requirement and the upper limit adjustment value.

In embodiments, determining the upper limit adjustment value of the transmission power corresponding to each transmission cycle includes: the greater a number of continuous and real-time services included in the service scenario, the smaller the upper limit adjustment value of the transmission power; or the smaller a number of non-continuous services and non-real-time services included in the service scenario, the smaller the upper limit adjustment value of the transmission power.

In embodiments, the method further incudes: determining the upper limit value of the transmission power corresponding to each transmission cycle according to a mapping relationship between a signal strength of the electronic device and an adjustment value.

In embodiments, determining the upper limit value of the transmission power corresponding to each transmission cycle according to the mapping relationship between the signal strength of the electronic device and the adjustment value includes: in response to the signal strength being within a first range, determining the adjustment value corresponding to the signal strength as a first adjustment value; in response to the signal strength being within a second range, determining the adjustment value corresponding to the signal strength as a second adjustment value; in response to the signal strength being within a third range, determining the adjustment value corresponding to the signal strength as a third adjustment value; and determining a sum of the limited power under the SAR requirement and the adjustment value corresponding to the signal strength as the upper limit value of the transmission power corresponding to each transmission cycle; in which, the first range, the second range and the third range form a value range of the signal strength, a lower limit of the first range is greater than an upper limit of the second range, and a lower limit of the second range is greater than an upper limit of the third range; the first adjustment value is greater than the second adjustment value, and the second adjustment value is greater than the third adjustment value.

In embodiments, the upper limit values corresponding to all transmission cycles in the preset time window are the same, or at least one upper limit value corresponding to at least one transmission cycle in the preset time window is different from the upper limit values corresponding to other transmission cycles.

In embodiments, determining the lower limit value of the transmission power corresponding to each transmission cycle includes: determining a lower limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and determining the lower limit value of the transmission power corresponding to each transmission cycle by obtaining a difference between a limited power under the SAR requirement and the lower limit adjustment value.

In embodiments, determining the lower limit adjustment value of the transmission power according to the service scenario includes: the greater a number of continuous and real-time services included in the service scenario, the smaller the lower limit adjustment value of the transmission power; or the greater a number of non-continuous services and non-real-time services included in the service scenario, the greater the lower limit adjustment value of the transmission power.

According to a second aspect of embodiments of the present invention, an apparatus for controlling a transmission power as defined in claim <NUM> is provided. The apparatus includes: a target number acquisition module configured to determine a target number of transmission cycles according to a service scenario of an electronic device, in which a preset time window is divided into the target number of transmission cycles, and the preset time window is a test cycle used in a specific absorption rate (SAR) test of the electronic device; a transmission power determination module configured to determine at least one of an upper limit value or a lower limit value of a transmission power corresponding to each transmission cycle, in which an average value of transmission powers in the preset time window complies with a SAR requirement; and a transmission power control module configured to control the electronic device to transmit and receive signals using a corresponding transmission power in each transmission cycle.

The target number acquisition module comprises: a first determination unit configured to determine that the greater a number of continuous and real-time services comprised in the service scenario, the greater a value of the target number; or a second determination unit configured to determine that the greater a number of non-continuous services and non-real-time services comprised in the service scenario, the smaller the value of the target number.

In embodiments, the transmission power determination module comprises: a first adjustment determination sub-module, configured to determine an upper limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and an upper limit value acquisition sub-module, configured to determine the upper limit value of the transmission power corresponding to each transmission cycle by obtaining a sum of a limited power under the SAR requirement and the upper limit adjustment value.

In embodiments, the transmission power determination module comprises: a second adjustment determination sub-module, configured to determine a lower limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and a lower limit value acquisition sub-module, configured to determine the lower limit value of the transmission power corresponding to each transmission cycle by obtaining a difference between a limited power under the SAR requirement and the lower limit adjustment value.

According to a third aspect of embodiments of the present invention, a non-transitory computer-readable storage medium is provided. When a computer program stored in the storage medium is executed by a processor, the above method is implemented.

It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory only, which will not limit the present invention.

The implementations set forth in the following description of exemplary embodiments do not represent all possible implementations consistent with the present invention. Instead, they are merely examples of apparatuses and methods consistent with aspects related to the present invention as recited in the appended claims. It should be noted that features in the following embodiments and implementations may be combined with each other without conflict.

For solving the above technical problem, embodiments of the present invention provide a method for controlling a transmission power. <FIG> is a flowchart of a method for controlling a transmission power according to an illustrative embodiment of the present invention. Referring to <FIG>, the method for controlling a transmission power may include blocks <NUM> to <NUM>.

At block <NUM>, a target number of transmission cycles is determined according to a service scenario of an electronic device. A preset time window is divided into the target number of transmission cycles, and the preset time window is a test cycle used in a specific absorption rate (SAR) test of the electronic device.

In an example, the electronic device may obtain a type of a current service. When the type of the current service is at least one of a non-continuous type and a non-real-time type, such as web pages, Weibo or uploading files, etc., the electronic device may determine that the service scenario of the electronic device is a first service scenario. When the type of the current service of the electronic device is a continuous and real-time type, such as calls, games, etc., the electronic device may determine that the service scenario of the electronic device is a second service scenario. When the type of the current service is a mixed business type, the electronic device may determine that the service scenario of the electronic device is a third service scenario, in which the mixed business type refers to including the continuous and real-time type and at least one of the non-continuous type and non-real-time type, or refers to that the current service includes both the continuous and real-time service and at least one of the non-continuous service and non-real-time service.

In an example, after determining the service scenario of the electronic device, the electronic device may determine the target number of the transmission cycles into which the preset time window is divided according to the above service scenario. The preset time window refers to the test cycle used in the compliance test for SAR of the electronic device. For example, International Commission on Non-Ionizing Radiation Protection (ICNIRP) and Federal Communications Commission (FCC) use different time windows. Taking a frequency band of sub6G as an example, the preset time window corresponding to ICNIRP is <NUM> and the preset time window corresponding to FCC is <NUM>. In related arts, one higher transmission power and one lower transmission power will be arranged within the above preset time window. In order to meet the SAR requirement, a time period when transmitting at low power is usually long, which is not conducive to the continuous and real-time service.

In an example, the electronic device may determine the target number of transmission cycles into which the preset time window is divided, as follows: the greater a number of continuous and real-time services included in the service scenario, the greater a value of the target number; or the greater a number of non-continuous services and non-real-time services included in the service scenario, the smaller the value of the target number.

The continuous and real-time service has a high requirement on real-time. Taking a call as an example, in related arts, only one time period in the preset time window adopts the higher transmission power to send and receive the signals (hereinafter referred to as a third time period), and quality of the call during the third time period is high. However, the remaining time period adopts the lower transmission power to send and receive the signals (hereinafter referred to as a fourth time period), and the quality of the call during the fourth time period is low, and even the problem of call interruption occurs.

In this embodiment, with dividing the preset time window into a plurality of transmission cycles, each transmission cycle includes one higher transmission power for transmitting and receiving the signals, that is, a first time period, and one lower transmission power for transmitting and receiving the signals, that is, a second time period, so the quality of the call in the first time period is high and the quality of the call in the second time period is low. Considering that when the number of the transmission cycles increases, a length of the second time period of each transmission cycle is less than a length of the fourth time period of the preset time window, that is, the second time period of each transmission cycle reaches the next transmission cycle before the quality of the call declines to affect the call (or the user feels the decline in the quality of the call), continuing to use the higher transmission power to send and receive the signals and resuming the high-quality call, achieving an effect of ensuring the high-quality call.

Taking three service scenarios as examples, the electronic device may determine the target number of the transmission cycles into which the preset time window is divided. The method may include that, when the service scenario is a first service scenario, the electronic device may determine that the target number of the transmission cycles is a first number; or when the service scenario is a second service scenario, the electronic device may determine that the target number of the transmission cycles is a second number; or when the service scenario is a third service scenario, the electronic device may determine that the target number of the transmission cycles is a third number. The third service scenario refers to that the type of the current service of the electronic device is a mixed service type. The first number is less than the third number, and the third number is less than the second number.

In some examples, considering a different proportion of the continuous and real-time services in the mixed service type, the third number may take a plurality of values, both falling within a range formed by taking the first number and the second number as endpoint values. It is understandable that appropriate values may be selected as the first number, the third number and the second number according to a specific scenario. For example, a value of the first number may be <NUM>, a value of the second number may be <NUM>, and the third number may take a value in a range of values from <NUM> to <NUM>. The corresponding solution falls into the protection scope of the present invention.

In some examples, the electronic device may store a mapping relationship between the service scenario and the target number. For example, a variety of service scenarios may be built according to service types supported by the electronic device, such as the first service scenario, the second service scenario and the third service scenario; then, the target number corresponding to each service scenario is determined. For example, the target number corresponding to the first service scenario may be <NUM>, the target number corresponding to the second service scenario may be <NUM>, and the target number corresponding to the third service scenario may take the value in the range of values from <NUM> to <NUM>. A data table, as a preset mapping relationship between the service scenario and the target number, may be obtained by mapping the service scenario and the target number one by one, and may be stored in a specified position, such as a cache, a local storage or a cloud. In this way, after obtaining the service scenario, the electronic device may query the above data table according to a scenario identification code of the service scenario to obtain the corresponding target number.

At block <NUM>, at least one of an upper limit value or a lower limit value of a transmission power corresponding to each transmission cycle is determined. An average value of transmission powers in the preset time window complies with a SAR requirement.

In an example, the electronic device may determine the at least one of the upper limit value and the lower limit value of the transmission power of the electronic device corresponding to each transmission cycle within the preset time window. The upper limit value of the transmission power refers to a maximum value of the transmission power of the electronic device in the first time period of the transmission cycle, and the lower limit value of the transmission power refers to a minimum value of the transmission power of the electronic device in the second time period of the transmission cycle. The first time period and the second time period form a transmission cycle, and a ratio of the first time period to the transmission cycle is a duty cycle of the upper limit value of the transmission power, and a ratio of the second time period to the transmission cycle is a duty cycle of the lower limit value of the transmission power. Understandably, the third one may be determined when any two of the upper limit value (or the lower limit value), the average value, and the duty cycle are known.

In an example, the electronic device may determine the upper limit value of the transmission power of the electronic device in each transmission cycle according to the service scenario, and keep the lower limit value of the transmission power unchanged. See <FIG>, the method may include blocks <NUM> to <NUM>.

At block <NUM>, the electronic device may determine an upper limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario. The upper limit values of the transmission power corresponding to all transmission cycles in the preset time window may be the same, or the upper limit value of the transmission power corresponding to at least one transmission cycle in the preset time window may be different from the upper limit values corresponding to other transmission cycles. Those skilled may select the upper limit value of the transmission power corresponding to each transmission cycle according to the specific service scenario.

In this block, the upper limit adjustment value refers to variation value of the power for the transmission power that may be increased on the basis of the limited power Plimit (such as 20dbm) corresponding to the SAR requirement, that is, the part of the power that may exceed the above limited power. The greater a number of continuous and real-time services included in the service scenario, the smaller the upper limit adjustment value of the transmission power; or the greater a number of non-continuous services and non-real-time services included in the service scenario, the greater the upper limit adjustment value of the transmission power. For example, when the service scenario is the first service scenario, the electronic device may determine that the upper limit adjustment value is a first adjustment value. For another example, when the service scenario is the second service scenario, the electronic device may determine that the upper limit adjustment value is a second adjustment value. For another example, when the service scenario is the third service scenario, the electronic device may determine that the upper limit adjustment value is a third adjustment value. The second adjustment value is less than the third adjustment value, and the third adjustment value is less than the first adjustment value.

In an example, the upper limit adjustment value may be set to a fixed value (such as 5dBm) or a dynamic value. When the upper limit adjustment value is a dynamic value, referring to <FIG>, the electronic device may obtain the upper limit adjustment value in the following way which may include blocks <NUM> to <NUM>.

At block <NUM>, the electronic device may obtain a present strength of transmission and reception signals of the electronic device. The present strength may be a strength of a transmission signal, a strength of a reception signal, or a quality of a channel between a terminal and a base station, which may be selected according to the specific scenario, and will not be limited hereinafter. Taking the present strength being the strength of the transmission signal (SITx) and the strength of the reception signal (SIRx) as an example, after obtaining the strength of the transmission signal and the strength of the reception signal, the electronic device may input the strength of the transmission signal and the strength of the reception signal into a preset formula y=a× SITX+b× SIRx+c, to obtain the present strength y. Those skilled may adjust a calculation manner according to the content of the present strength, and the corresponding solution falls into the protection scope of the present invention.

At block <NUM>, the electronic device may determine a signal state of the electronic device according to the present strength and preset strength ranges, and determine an adjustment value corresponding to the present strength according to a preset mapping relationship between the signal state and the adjustment value. Continuing with taking the present strength being the strength of the transmission signal (SITx) and the strength of the reception signal (SIRx) as an example, the electronic device may set three preset strength ranges, namely, a first range, a second range and a third range. The first range, the second range and the third range form a value range of the strength of the transmission and reception signals of the electronic device. Each value in the first range is greater than each value in the second range, and each value in the second range is greater than each value in the third range. After obtaining the present strength, the electronic device may compare the present strength with each preset strength range to determine which preset strength range the present strength is within, and obtain the adjustment value corresponding to the preset strength range.

For example, when the present strength is within the first range, the electronic device may determine that the adjustment value corresponding to the present strength is a first preset adjustment value according to the preset mapping relationship between the signal state and the adjustment value. For another example, when the present strength is within the second range, the electronic device may determine that the adjustment value corresponding to the present strength is a second preset adjustment value. For another example, when the present strength is within the third range, the electronic device may determine that the adjustment value corresponding to the present strength is a third preset adjustment value. It should be noted that the signal state may be set according to the specific scenario, such as four signal states, and the corresponding solution falls into the protection scope of the present invention.

In this way, this example may set different upper limit adjustment values at different signal strengths, that is, the upper limit adjustment value decreases as the signal becomes weaker, which is conducive to reducing the transmission power, so as to avoid a too large duty cycle of the transmission power in the second period of the transmission cycle, and avoid the problem of uplink signal deterioration.

At block <NUM>, the electronic device may determine the upper limit value of the transmission power corresponding to each transmission cycle by obtaining a sum of a limited power under the SAR requirement and the upper limit adjustment value.

The electronic device may determine the transmission power of the electronic device in the first time period of each transmission cycle according to the limited power under the SAR requirement and the upper limit adjustment value, that is, the upper limit value is equal to the sum of the limited power and the upper limit adjustment value. For example, when the limited power Plimit is 15dBm and the upper limit adjustment value is 3dBm, the transmission power Pmax of electronic device in each transmission cycle is <NUM>+<NUM>=18dBm and the effect is shown in <FIG>.

Referring to <FIG>, the left side illustrates a curve of the transmission power in the preset time window in the related art. For example, within <NUM>~<NUM>, it includes one third time period (<NUM>~<NUM>, 24dBm) and one fourth time period (<NUM>~<NUM>, 12dBm). The right side illustrates a curve of the transmission power of each cycle in the two transmission cycles in the present invention. For example, within <NUM>~<NUM>, it includes two first time periods (<NUM>~<NUM>, <NUM>~<NUM>, 24dBm) and two second time periods (<NUM>~<NUM>, <NUM>~<NUM>, 12dbm). Comparing the left side and the right side of <FIG> shows that, within the preset time window of the electronic device, the number of the first time periods (such as <NUM>) on the right side increases compared with the number of the third time period (such as <NUM>) on the left side.

Continuing to refer to <FIG>, when the upper limit values of the transmission power on the left side and the right side are the same, the length of the third time period in the preset time window on the left is equal to a sum of the lengths of the first time periods in all transmission cycles on the right. The difference is that the increase in the number of the transmission cycles on the right causes an increase in a frequency of entering the first time period in the preset time window. Each first time period adopts the upper limit value to send and receive the signals, which may improve the quality of communication.

Referring to <FIG>, the upper limit value of the transmission power in the transmission cycle on the right side is less than the upper limit value of the transmission power on the left side, compared with the upper limit value shown in <FIG>, wherein the change of the upper limit value is shown by a dotted line in <FIG>. The sum of the lengths of the first time periods of all transmission cycles on the right side increases, causing the duty cycle of the larger transmission power in the preset time window to increase, which is conducive to improving the quality of the communication.

In another example, the electronic device may determine the lower limit value of the transmission power of the electronic device and keep the upper limit value unchanged. Referring to <FIG>, the method may include blocks <NUM> and <NUM>. At block <NUM>, the electronic device may determine the lower limit adjustment value of the transmission power according to the service scenario. The lower limit adjustment value refers to variation value of the power for the transmission power that may be decreased on the basis of the limited power Plimit corresponding to the SAR requirement, that is, the part of the power that may be lower than the limited power. At block <NUM>, the electronic device may determine the lower limit value of the transmission power corresponding to each transmission cycle by obtaining a difference between the limited power under the SAR requirement and the lower limit adjustment value.

Understandably, the lower limit adjustment value may be set to a fixed value (such as 3dBm) or a dynamic value. When the lower limit adjustment value is the dynamic value, the setting manner may refer to the setting manner of the upper limit adjustment value. That is, the lower limit adjustment value may be determined according to the signal state of the electronic device, and the value of the lower limit adjustment value obtained under a condition that the second time period may be shortened or the transmission power within the second time period may be increased falls into the protection scope of the present invention.

In an example, when the lower limit adjustment value is a dynamic value, the electronic device may determine the lower limit adjustment value according to the present service scenario. For example, when the service scenario is the first service scenario, the electronic device may determine that the lower limit adjustment value is a fourth preset adjustment value (such as 4dBm). For another example, when the service scenario is the second service scenario, the electronic device may determine that the lower limit adjustment value is a fifth preset adjustment value (such as 1dBm). When the service scenario is the third service scenario, the electronic device may determine that the lower limit adjustment value is a sixth preset adjustment value (such as 3dBm). In this example, the fourth preset adjustment value is greater than the sixth preset adjustment value, and the sixth preset adjustment value is greater than the fifth preset adjustment value. Taking the fourth preset adjustment value greater than the sixth preset adjustment value as an example, it is to provide a larger lower transmission power for the third service scenario, that is, the transmission power in the second time period of each transmission cycle becomes larger.

The electronic device may determine the transmission power of the electronic device in the second time period of each transmission cycle according to the limited power under the SAR scene and the lower limit adjustment value. For example, when the limited power Plimit is 20dBm and the lower limit adjustment value is 6dBm, the lower limit value of the transmission power of the electronic device in each transmission cycle is <NUM>-<NUM>=14dBm, and the effect is shown in <FIG>.

Referring to <FIG>, the left side illustrates a curve of the transmission power in the preset time window in the related art. For example, within <NUM>~<NUM>, it includes one third time period (<NUM>~<NUM>, 24dBm) and one fourth time period (<NUM>~<NUM>, 12dBm). The right side illustrates a curve of the transmission power of each cycle in the two transmission cycles in the present invention. For example, within <NUM>~<NUM>, it includes two first time periods (<NUM>~<NUM>, <NUM>~<NUM>, 24dBm) and two second time periods (<NUM>~<NUM>, <NUM>~<NUM>, 14dbm). Comparing the left side and the right side of <FIG> shows that, within the preset time window of the electronic device, the number of the first time periods (such as <NUM>) on the right side increases compared with the number of the third time period (such as <NUM>) on the left side, causing an increase in the frequency of entering the first time period in the preset time window. Each first time period adopts the upper limit value to send and receive the signals, which may improve the quality of the communication. And the transmission power of each second time period on the right side is 2dBm higher than that of the second time period on the left side, which may also improve the quality of the communication during the second time period.

It should be noted that the solution in <FIG> illustrates the solution of adjusting the upper limit value of the transmission power corresponding to each transmission cycle, and the solution in <FIG> illustrates the solution of adjusting the lower limit value of the transmission power corresponding to each transmission cycle. In another example, in order to better adjust the transmission power corresponding to each transmission cycle, the solutions of <FIG> and <FIG> may be combined, and the upper limit value and lower limit value of the transmission power may be adjusted simultaneously. The combined solution falls within the protection scope of the present invention.

At block <NUM>, the electronic device is controlled to transmit and receive signals using a corresponding transmission power in each transmission cycle.

So far, according to the solution provided by embodiments of the present invention, the target number of the transmission cycles into which the preset time window is divided may be determined according to the service scenario of the electronic device. The preset time window refers to the test cycle used in the compliance test for SAR of the electronic device. The at least one of the upper limit value and the lower limit value of the transmission power corresponding to each transmission cycle is determined. The average value of transmission power in the preset time window complies with the SAR requirement. The electronic device is controlled to transmit and receive the signals using the corresponding transmission power in each transmission cycle. In this embodiment, the preset time window is divided into the target number of transmission cycles, so that the upper limit value may be used to transmit and receive the signals in each transmission cycle, or the frequency of transmitting and receiving the signals with the upper limit value is increased, which may improve the quality of the signals under the condition of meeting the requirements of SAR, avoid problems of silent or dropped calls, and improve experience of using the electronic device.

On the basis of the method for controlling a transmission power provided by embodiments of the present invention, embodiments of the present invention also provide an apparatus for controlling a transmission power, applicable to an electronic device. Referring to <FIG>, the apparatus includes:.

In embodiments, the target number acquisition module includes: a first determination unit configured to determine that the greater a number of continuous and real-time services included in the service scenario, the greater a value of the target number; and a second determination unit configured to determine that the greater a number of non-continuous services and non-real-time services included in the service scenario, the smaller the value of the target number.

In embodiments, the target number acquisition module includes:
a first number determination unit configured to, when the service scenario is a first service scenario, determine that the target number of the transmission cycles is a first number, in which, the first service scenario refers to that a type of a current service of the electronic device is at least one of a non-continuous type and a non-real-time type; or, a second number determination unit configured to, when the service scenario is a second service scenario, determine that the target number of the transmission cycles is a second number, in which, the second service scenario refers to that the type of the current service of the electronic device is a continuous and real-time type; or, a third number determination unit configured to, when the service scenario is a third service scenario, determine that the target number of the transmission cycles is a third number, in which the third service scenario refers to that the type of the current service of the electronic device is a mixed service type which refers to including the continuous and real-time type and at least one of the non-continuous type and non-real-time type; in which the first number is less than the third number, and the third number is less than the second number.

In embodiments, the transmission power determination module includes: a first adjustment determination sub-module configured to determine an upper limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and an upper limit value acquisition sub-module configured to determine the upper limit value of the transmission power corresponding to each transmission cycle by obtaining a sum of a limited power under the SAR requirement and the upper limit adjustment value.

In embodiments, the transmission power determination module includes: a first adjustment determination unit configured to determine that the greater a number of continuous and real-time services included in the service scenario, the smaller the upper limit adjustment value of the transmission power; and a second adjustment determination unit configured to determine that the greater a number of non-continuous services and non-real-time services included in the service scenario, the greater the upper limit adjustment value of the transmission power.

Alternatively, the apparatus further includes an upper-limit-value determination module configured to determine the upper limit value of the transmission power corresponding to each transmission cycle according to a mapping relationship between a present strength of transmission and reception signals of the electronic device and an adjustment value.

Alternatively, the upper-limit-value determination module includes: a third determination unit configured to, when the present strength is within a first range, determine that the adjustment value corresponding to the present strength is a first preset adjustment value; a fourth determination unit configured to, when the present strength is within a second range, determine that the adjustment value corresponding to the present strength is a second preset adjustment value; a fifth determination unit configured to, when the present strength is within a third range, determine that the adjustment value corresponding to the present strength is a third preset adjustment value; and a sixth determination unit configured to determine a sum of the limited power under the SAR requirement and the adjustment value corresponding to the present strength as the upper limit value of the transmission power corresponding to each transmission cycle; in which, the first range, the second range and the third range form a value range of strength of the transmission and reception signals; the first preset adjustment value, the second preset adjustment value, and the third preset adjustment value decreases sequentially.

In embodiments, the upper limit values corresponding to all transmission cycles in the preset time window are the same, or the upper limit value corresponding to at least one transmission cycle in the preset time window is different from the upper limit values corresponding to other transmission cycles.

In embodiments, the transmission power determination module includes: a second adjustment determination sub-module configured to determine a lower limit adjustment value of the transmission power corresponding to each transmission cycle according to the service scenario; and a lower limit value acquisition sub-module configured to determine the lower limit value of the transmission power corresponding to each transmission cycle by obtaining a difference between a limited power under the SAR requirement and the lower limit adjustment value.

Alternatively, the second adjustment determination sub-module includes: a first adjustment determination sub-module configured to determine that the greater a number of continuous and real-time services included in the service scenario, the smaller the lower limit adjustment value of the transmission power; or a second adjustment determination sub-module configured to determine that the greater a number of non-continuous services and non-real-time services included in the service scenario, the greater the lower limit adjustment value of the transmission power.

It should be noted that the apparatuses and devices shown in embodiments match the contents of the method embodiments, and may refer to the contents of the above-mentioned method embodiments, which will not be repeated here.

<FIG> is a block diagram of an electronic device according to an illustrative embodiment of the present invention. For example, the electronic device <NUM> may be a smartphone, a computer, a digital broadcasting terminal, a tablet device, a medical device, a fitness device, a personal digital assistant, etc..

As illustrated in <FIG>, the electronic device <NUM> may include one or more of the following components: a processing component <NUM>, a memory <NUM>, a power component <NUM>, a multimedia component <NUM>, an audio component <NUM>, an input/output (I/O) interface <NUM>, a sensor component <NUM>, a communication component <NUM> and an image capturing component <NUM>.

The processing component <NUM> typically controls overall operations of the electronic device <NUM>, such as the operations associated with display, telephone calls, data communications, camera operations, and recording operations. The processing component <NUM> may include one or more processors <NUM> to execute instructions.

The memory <NUM> is configured to store various types of data to support the operation of the electronic device <NUM>. Examples of such data include instructions for any applications or methods operated on the electronic device <NUM>, contact data, phonebook data, messages, pictures, video, etc. The memory <NUM> may be implemented using any type of volatile or non-volatile memory devices, or a combination thereof, such as a static random access memory (SRAM), an electrically erasable programmable read-only memory (EEPROM), an erasable programmable read-only memory (EPROM), a programmable read-only memory (PROM), a read-only memory (ROM), a magnetic memory, a flash memory, a magnetic or optical disk.

The power component <NUM> provides power to various components of the electronic device <NUM>. The power component <NUM> may include a power management system, one or more power sources, and any other components associated with the generation, management, and distribution of power in the electronic device <NUM>. The power module <NUM> may include a power chip, and the controller may communicate with the power chip, to control the power chip to turn on or turn off switches, to enable a battery to supply power to a motherboard circuit or not.

The multimedia component <NUM> includes a screen providing an output interface between the electronic device <NUM> and the user.

The audio component <NUM> is configured to output and/or input audio signals. For example, the audio component <NUM> includes a microphone ("MIC") configured to receive an external audio signal when the electronic device <NUM> is in an operation mode, such as a call mode, a recording mode, and a voice recognition mode. The received audio signal may be further stored in the memory <NUM> or transmitted via the communication component <NUM>. In some embodiments, the audio component <NUM> also includes a speaker for outputting an audio signal.

The sensor component <NUM> includes one or more sensors to provide status assessments of various aspects of the electronic device <NUM>. For instance, the sensor component <NUM> may detect an open/closed status of the electronic device <NUM>, relative positioning of components, e.g., the display and the keypad, of the electronic device <NUM>, a change in position of the electronic device <NUM> or a component of the electronic device <NUM>, a presence or absence of a target object contact with the electronic device <NUM>, an orientation or an acceleration/deceleration of the electronic device <NUM>, and a change in temperature of the electronic device <NUM>. In an example, the sensor component <NUM> may include a magnetic sensor, a gyroscope, and a magnetic field sensor, and the magnetic field sensor may include at least one of a Hall sensor, a thin film magnetoresistance sensor, and a magnetic fluid acceleration sensor.

The communication component <NUM> is configured to facilitate communication, wired or wirelessly, between the electronic device <NUM> and other devices. The electronic device <NUM> can access a wireless network based on any communication standard, such as WiFi, <NUM>, or <NUM>, or a combination thereof. In one exemplary embodiment, the communication component <NUM> receives a broadcast signal or broadcast associated information from an external broadcast management system via a broadcast channel. In one exemplary embodiment, the communication component <NUM> further includes a near field communication (NFC) module to facilitate short-range communications. For example, the NFC module may be implemented based on a radio frequency identity (RFID) technology, an infrared data association (IrDA) technology, an ultra-wideband (UWB) technology, a Bluetooth (BT) technology, and other technologies.

In exemplary embodiments, the electronic device <NUM> may be implemented with one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), controllers, micro-controllers, microprocessors, or other electronic components.

In exemplary embodiments, there is also provided a non-transitory readable storage medium including an executable computer program, such as a memory <NUM> including instructions, the above executable computer program may be executed by a processor. For example, the readable storage medium may be a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disc, an optical data storage device, and the like.

Other embodiments of the present invention are obvious for those skilled in the art after considering the description and practicing the invention disclosed herein. This invention is intended to cover any variations, uses, or adaptive changes that follow the general principles of this invention and include common general knowledge or customary technical means in the technical field not disclosed in this invention. The description and examples are to be considered exemplary only, and the true scope of this invention is indicated by claims below.

Claim 1:
A method for controlling a transmission power, comprising:
determining (<NUM>) a target number of transmission cycles according to a type of current services of an electronic device, wherein a preset time window is divided into the target number of transmission cycles, and the preset time window is a test cycle used in a specific absorption rate, SAR, test of the electronic device;
determining (<NUM>) at least one of an upper limit value or a lower limit value of a transmission power corresponding to each transmission cycle, wherein an average value of transmission powers in the preset time window complies with a SAR requirement; and
controlling (<NUM>) the electronic device to transmit and receive signals using the transmission power corresponding to each transmission cycle in each transmission cycle;
wherein determining (<NUM>) the target number of transmission cycles according to the type of current services of the electronic device comprises:
the greater a number of real-time services comprised in the current services of the electronic device, the greater a value of the target number; or
the greater a number of non-real-time services comprised in the current services of the electronic device, the smaller the value of the target number.