KR20060032287A - RF transmission power compensation device and method in mobile communication terminal - Google Patents

Abstract

The present invention amplifies or attenuates RF transmission power based on a difference value of each channel between AGC signal level values and transmission power level values measured at room temperature in a mobile communication terminal, such as at room temperature even in a low temperature or high temperature environment. An apparatus and method for compensating RF transmission power in a mobile communication terminal capable of maintaining power.

The present invention calculates a difference between a signal level value for an AGC (Automatic Gain Control) signal and a transmission power level value for an RF transmission signal output from a duplexer in an arbitrary channel and temperature environment in which a mobile communication terminal is driven. By adjusting the gain of the driving amplifier according to the result of comparing the difference value with the transmission power control reference value of the corresponding channel measured at room temperature, it does not give a uniform compensation value for all the channels as before, but it automatically changes according to the temperature change. It is possible to compensate RF transmission power of each channel, and by investing a lot of time and effort at low temperature or high temperature, and using each channel's transmission power control reference value measured at room temperature without finding compensation value for each temperature. It is possible to maintain the same RF transmit power at room temperature even in low or high temperature environments.

Mobile communication terminal, RF transmit signal, drive amplifier, AGC signal level, transmit power level, room temperature, transmit power compensation

Description

Apparatus And Method For Compensating RF Transmission Power In The Mobile Communication Terminal}

1 is a diagram illustrating an RF transmitter of a conventional mobile communication terminal.

2 is a diagram illustrating an RF transmitter for RF transmission power compensation in a mobile communication terminal according to the present invention.

3 is a flowchart illustrating an RF transmission power compensation operation in a mobile communication terminal according to the present invention.

4 is a diagram illustrating a difference between an AGC signal level value and a transmission power level value according to temperature change for each channel in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

21: drive amplifier 22: SAW filter

23: power amplifier 24: duplexer

25: AC-DC converter 26: memory unit

27: MSM

The present invention relates to RF transmission power control in a mobile communication terminal, and more particularly, in a terminal based on a difference between an automatic gain control (AGC) signal level value and a transmission power level value measured for each channel (frequency band) at room temperature. RF transmission power compensation device in a mobile communication terminal that maintains RF transmission power at room temperature in a low or high temperature environment by amplifying or attenuating RF transmission power output differently according to temperature change for each channel used And to a method.

Recently, with the rapid development of mobile communication technology, most people use various kinds of mobile communication terminals such as PCS phones, cellular phones, PDAs, notebooks, and the like.

The mobile communication terminal amplifies RF (Radio Frequency) signals, which are various control data and voice data signals, to a predetermined power level and transmits and receives them through an antenna. In this case, a power amplifier is used for power amplification.

That is, the RF transmitter of the conventional mobile communication terminal, as shown in Figure 1, the SAW filter (or band pass filter) 12 for band-filtering and outputting the RF signal for transmission, and the SAW filter 12 A power amplifier module (PAM) 13 for amplifying a predetermined level power of the RF signal output from the power amplifier; and a duplexer 14 for transmitting the RF signal amplified by the power amplifier 13 through an antenna. ).                         

In addition, in order to control the maximum transmission power in the RF transmitter, an AC-DC converter 15 for converting an RF signal output from the power amplifier 13 into a DC signal and outputting a transmission power value is provided with a power amplifier 13 and a duplexer. And a gain adjusting PDM signal with reference to the transmission power value output from the AC-DC converter 15, and adjusting the gain of the drive amplifier 11 with the PDM signal to adjust the RF signal. It has a configuration that includes a mobile station modem (MSM) (16) which is a terminal control unit to maintain the maximum transmission power of the constant level.

When the AC-DC converter 15 is not configured in the mobile communication terminal, the maximum transmission power is adjusted using data measured by software.

On the other hand, the operating temperature range of the above-described mobile communication terminal is a minimum '-30 degrees' to a maximum '60 degrees', and should satisfy the same RF transmission power as at room temperature in a low temperature and high temperature environment as well as at room temperature (25 degrees). In case of filters such as SAW filter 12 or duplexer 14, amplitude fluctuations are severe according to temperature change, there are variations between channels (frequency bands) due to ripple, and shift phenomenon is caused by temperature change. As it occurs, each channel has a different filter shape.

However, in the conventional mobile communication terminal, the transmission power compensation according to the temperature change does not compensate for a wide bandwidth for each channel, but instead applies a compensation value of a specific channel when compensating for transmission power of another channel uniformly, unlike at room temperature. In the low temperature or high temperature environment, there is a problem in that the maximum transmission power and error and accurate compensation is not achieved, and there is also a problem in that accurate maximum transmission power compensation is difficult due to the difference in characteristics of each sample.

In addition, in the related art, in order to find a compensation value for each temperature, the transmission power according to the temperature change such as dividing the terminal operating temperature range (-30 degrees to 60 degrees) into several equal parts (for example, eight equal parts) to find the compensation value for each temperature. There was a problem that it takes a lot of time and effort to compensate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a signal level value for an AGC signal and a transmission power for an RF transmission signal output from a duplexer in an arbitrary channel and temperature environment in which a mobile communication terminal is driven. By calculating the difference of the level value and comparing the difference value with the transmission power control reference value of the corresponding channel measured at room temperature, the gain of the driving amplifier is adjusted so that the uniform compensation value for all channels is maintained as before. It is not to give, but to automatically compensate for the RF transmit power of each channel as the temperature changes.

Another object of the present invention is to use a transmission power control reference value for each channel measured at room temperature without having to find a compensation value for each temperature by investing a lot of time and effort at low temperature or high temperature, even at low temperature or high temperature environment for each channel. To maintain the RF transmit power such as

A feature of the present invention for solving the above object is a drive amplifier for outputting the AGC signal used to amplify the RF signal for transmission output to the power amplifier; An AC-DC converter converting an RF transmission signal output from the duplexer into a DC signal through the power amplifier and the driving amplifier and outputting a corresponding transmission power level value; A memory unit storing a difference value of each channel between the AGC signal level value and the transmission power level value measured at room temperature as a transmission power control reference value to control the RF transmission power output from the duplexer; After calculating the difference between the AGC signal level value corresponding to the AGC signal output from the drive amplifier and the transmission power level value output from the AC-DC converter, the difference value and the transmission of the corresponding channel stored in the memory unit Comparing a power control reference value to determine a drive amplifier compensation value, and generates a control signal based on the compensation value to adjust the gain of the drive amplifier by controlling the terminal control unit for compensating and output the RF transmission power output from the duplexer It is to provide an RF transmission power compensation device in a mobile communication terminal.

Here, the AC-DC converter is implemented by a DC rectifier circuit composed of a diode, a resistor, and a capacitor to convert the RF transmission signal output from the duplexer to a DC signal.

According to another aspect of the present invention, a transmission power control reference value for each channel corresponding to a difference between an AGC signal level value of a driving amplifier and a transmission power level value of a duplexer measured at room temperature for RF transmission power compensation in a mobile communication terminal is stored in a memory. Storing; Outputting an AGC signal corresponding to the control signal to the terminal controller in a driving amplifier for amplifying the RF transmission signal according to the control signal in an arbitrary channel and temperature environment and outputting the RF signal to the power amplifier; Converting an RF transmission signal output from a duplexer into a DC signal through the power amplifier and outputting a corresponding transmission power level value to the terminal controller; After calculating a difference value between the AGC signal level value output from the driving amplifier and the transmission power level value, and comparing the difference value and the transmission power control reference value stored in the memory to amplify or attenuate the RF transmission power. Determining a compensation value; Compensating the RF transmission power output from the duplexer by generating a new control signal on the basis of the compensation value determined in the above to adjust the gain of the driving amplifier to output the RF transmission power compensation method in a mobile communication terminal To provide.

Here, the transmission power level value input to the terminal controller is a power level value corresponding to the RF transmission signal output through the power amplifier and the duplexer sensitive to the temperature change, and corresponds to each channel and temperature change used in the terminal. Accordingly, different transmission power level values are input.

The process of compensating and outputting the RF transmission power may include a lower transmission power level at room temperature when the mobile communication terminal uses a channel of a low frequency band in a low temperature environment or a channel of a high frequency band in a high temperature environment. A value is inputted to the terminal control unit. As a result, a difference value between the AGC signal level and the transmission power level value is calculated to be smaller than the transmission power control reference value stored in the memory. By amplifying the gain, the RF transmission power output from the duplexer is amplified and compensated by the same RF transmission power as at room temperature.

In addition, the process of compensating and outputting the RF transmission power may include a higher transmission power level at room temperature when the mobile communication terminal uses a channel of a high frequency band in a low temperature environment or a channel of a low frequency band in a high temperature environment. The value is inputted to the terminal control unit. As a result, a difference between the AGC signal level value and the transmission power level value is calculated to be larger than the transmission power control reference value stored in the memory. By attenuating the gain, the RF transmission power output from the duplexer is attenuated and compensated by the same RF transmission power as at room temperature.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, by compensating the RF transmission power according to the temperature change of the mobile communication terminal for each channel, so as to maintain the RF transmission power as at room temperature even in a low temperature or high temperature environment, the RF transmitter of the mobile communication terminal is attached to the accompanying drawings. It has a configuration as shown in FIG.

That is, the configuration of the RF transmitter for RF transmission power compensation output from the mobile communication terminal according to the present invention as shown in Figure 2, the drive amplifier 21, SAW filter (or band pass filter) 22 ), A power amplifier 23, a duplexer 24, an AC-DC converter 25, a memory unit 26, and an MSM 27.

Here, since the SAW filter 22, the power amplifier 23 and the duplexer 24 performs the same function as the conventional configuration, a description of the function will be omitted.

In addition, the driving amplifier 21 adjusts the gain by an AGC (Automatic Gain Control) signal, which is a PDM signal output for gain control from the MSM 27, and thus an up-mixer (not shown). ) Amplifies the RF RF signal generated and mixed by transmitting the IF signal for transmission and the carrier oscillation frequency by the gain adjusted before and outputs it to the SAW filter 22, and also uses the AGC signal used for controlling its gain. To the MSM (27) side.

The AC-DC converter 25 is connected to the RF signal output terminal of the duplexer 24, converts the RF signal output from the duplexer 24 into a DC signal, and converts the current transmit power level value to the MSM 27 side. Since the RF signal output from the duplexer 24 has a large signal level, it is preferable to implement the DC rectifier circuit composed of a diode, a resistor, and a capacitor.

The memory unit 26 stores a reference value for controlling the RF transmission power, and calculates a difference between the AGC signal level value and the transmission power level value for the RF transmission output for each channel (frequency band) at room temperature (25 degrees). It is stored as a transmission power control reference value.

The MSM 27 is a terminal controller for controlling and managing the overall operation of the terminal. The MSM 27 is an AGC signal level value obtained by converting the AGC signal output from the driving amplifier 21 into a DC signal and is output from the AC-DC converter 25. After calculating the difference between the transmission power level values, the difference value is compared with the transmission power control reference value corresponding to the currently used channel stored in the memory unit 26 to determine a compensation value for amplifying or attenuating the RF transmission power. By controlling the gain of the driving amplifier 21 by generating a PDM signal based on the compensation value, the RF transmission power output to the outside through the antenna is compensated with the same RF transmission power as at room temperature and controlled to be output.

The RF transmission power compensation operation in the mobile communication terminal according to the present invention having such a configuration will be described with reference to FIG. 3 as follows.

First, in order to maintain the RF transmission power output through the antenna from the duplexer 24 of the RF transmission unit at a predetermined level, the reference value for each channel for controlling the RF transmission power should be stored in the memory unit 26. To this end, the frequency band (channel) used at room temperature is divided into, for example, 16 equal parts corresponding to the difference between the AGC signal level value output from the drive amplifier 21 and the transmission power level value output from the AC-DC converter 25. The transmission power control reference value is stored in the memory unit 26 (step S31). At this time, as illustrated in (a) of FIG. 4, the AGC signal level value (for example, the voltage value of the AGC signal) A output from the driving amplifier 21 is constant for each channel, but AC-DC The transmission power level value (for example, the voltage value of the RF transmission signal) B output from the converter 25 has a different level value for each channel, and thus, the transmission power control reference value stored in the memory unit 26 is also provided. Each channel has a different reference value.

In this state in which the transmission power control reference value is stored in the memory unit 26, the RF signal for transmission output from the up-mixer in the driving amplifier 21 according to the amplification gain adjustment using the PDM signal of the MSM 27 is applied. The gain is amplified by the SAW filter 22 and output.

In addition, the driving amplifier 21 amplifies the RF signal for transmission and outputs it to the SAW filter 22, while outputting the AGC signal corresponding to the PDM signal of the MSM 27 to the MSM 27 side (step S32). In this case, the AGC signal input to the MSM 27 is a signal that is not sensitive to temperature change, and is used as a reference value when changing the temperature because the AGC signal is output as a signal at room temperature even in a low temperature or high temperature environment.

When the RF signal amplified by the driving amplifier 21 is band-filtered by the SAW filter 22 and output to the power amplifier 23, the power amplifier 23 outputs the RF output from the SAW filter 22. The signal is amplified at a constant level and output to the duplexer 24.

Then, the duplexer 24 outputs the RF signal for transmission amplified by the power amplifier 23 to the base station through the antenna, and the AC-DC converter 25 outputs the RF signal output from the duplexer 24. The signal is converted into a signal and outputs a corresponding transmission power level value to the MSM 27 (step S33). At this time, the transmission power level value input to the MSM 27 is sensitive to temperature changes. And a power level value corresponding to the RF signal output through the power amplifier 23 and the duplexer 24, which is the AGC signal level value output from the driving amplifier 21, as illustrated in FIG. Unlike (A) having a constant level value independent of each channel and temperature, the transmission power level value (B) is not only different for each channel, but also different from the normal temperature in a low temperature or high temperature environment. ).

Accordingly, the MSM 27 calculates a difference value between the AGC signal level value input from the drive amplifier 21 and the transmission power level value input from the AC-DC converter 25 in a low or high temperature environment (step S34). The RF value is output through the antenna by comparing the difference value with the transmission power control reference value corresponding to the current use channel stored in the memory unit 26, that is, the transmission power control reference value corresponding to the current use channel measured at room temperature. The drive amplifier compensation value for amplifying or attenuating the current RF transmission power is determined so that the power maintains the same RF transmission power as at room temperature (step S35).

Thereafter, the MSM 27 calculates a driving amplifier based on the compensation value determined above (that is, a compensation value for amplifying or attenuating the RF transmission power output from the current duplexer 24 based on the RF transmission power measured at room temperature). By generating a new PDM signal for controlling the gain of 21) and adjusting the gain of the driving amplifier 21, the RF transmission power output from the duplexer 24 to the outside through the antenna is finally transmitted as at room temperature. The power is compensated for and output (step S36).

For example, when the mobile communication terminal is driven in a low temperature environment, the AGC signal level value input from the driving amplifier 21 is not sensitive to a change in temperature, but is input at the same AGC signal level value as at room temperature. The transmit power level value input from the converter 25 is input as a transmit power level value different from normal temperature because the SAW filter 22, the power amplifier 23, the duplexer 24, and the like are sensitive to temperature changes. .

If the mobile communication terminal currently uses a relatively low frequency band (channel), as illustrated in (b) of FIG. 4, the transmit power level value input from the AC-DC converter 25 has a lower transmit power at room temperature. The difference value between the AGC signal level value and the transmission power level value, which is input as a level value, and therefore input at low temperature, is further compared with the difference value between the AGC signal level value and the transmission power level value measured at room temperature, that is, the transmission power control reference value. As a result, the MSM 27 determines a compensation value for amplifying the RF transmission power output in the current state and generates a new PDM signal based on the amplification compensation value. By further amplifying the gain of a), the final RF transmit power is amplified to the same RF transmit power as at room temperature.

In addition, when the mobile communication terminal currently uses a relatively high frequency band (channel), as illustrated in (b) of FIG. 4, the transmission power level value input from the AC-DC converter 25 has a higher transmission power at room temperature. The difference value between the AGC signal level value and the transmission power level value inputted as the level value and thus input at low temperature is confirmed to have a larger difference value when compared with the transmission power control reference value measured at room temperature. ) Determines a compensation value for attenuating the RF transmission power output in the current state, and then generates a new PDM signal based on the attenuation compensation value to further attenuate the gain of the driving amplifier 21 to finally output the RF transmission power. Is attenuated and compensated by the same RF transmission power as at room temperature.                     

On the contrary, when the mobile communication terminal uses a relatively low frequency band (channel) in a high temperature environment, the transmission power level value input from the AC-DC converter 25 is input as a higher transmission power level value at room temperature, and thus a low temperature. The difference value between the AGC signal level value and the transmit power level value inputted from is determined to have a difference value greater than the transmit power control reference value measured at room temperature. Accordingly, the MSM 27 determines the RF transmit power output in the current state. After determining the compensation value for attenuation, a new PDM signal is generated based on the attenuation compensation value to further attenuate the gain of the driving amplifier 21 so that the final output RF transmission power is attenuated to the same RF transmission power as at room temperature. do.

In addition, when the mobile communication terminal uses a relatively high frequency band (channel) in a high temperature environment, the transmission power level value input from the AC-DC converter 25 is input as a lower transmission power level value at room temperature, and thus a low temperature. The difference value between the AGC signal level value and the transmit power level value inputted from is determined to have a difference value smaller than the transmit power control reference value measured at room temperature. Accordingly, the MSM 27 determines the RF transmit power output in the current state. After determining the compensation value for amplification, a new PDM signal is generated based on the amplification compensation value to further amplify the gain of the driving amplifier 21, thereby amplifying the final output RF transmission power with the same RF transmission power at room temperature. Will be printed.

In addition, the embodiment according to the present invention is not limited to the above-described embodiments, and various alternatives, modifications, and changes can be made within the scope apparent to those skilled in the art.

As described above, the present invention calculates the difference between the signal level value for the AGC signal and the transmission power level value for the RF transmission signal output from the duplexer in any channel and temperature environment in which the mobile communication terminal is driven, and the difference. By adjusting the gain of the driving amplifier according to the result of comparing the value with the transmission power control reference value of the corresponding channel measured at room temperature, it automatically adjusts each temperature according to the temperature change instead of giving a uniform compensation value for all channels as before. The RF transmit power can be compensated for each channel, and the low temperature for each channel using only the transmission power control reference value for each channel measured at room temperature without having to find a compensation value for each temperature by investing a lot of time and effort at low or high temperatures. In the high temperature environment, the same RF transmission power as at room temperature can be maintained.

Claims (6)

A driving amplifier for outputting an AGC signal used to amplify the RF signal for transmission output to the power amplifier; An AC-DC converter converting an RF transmission signal output from the duplexer into a DC signal through the power amplifier and the driving amplifier and outputting a corresponding transmission power level value; A memory unit storing a difference value of each channel between the AGC signal level value and the transmission power level value measured at room temperature as a transmission power control reference value to control the RF transmission power output from the duplexer; After calculating the difference between the AGC signal level value corresponding to the AGC signal output from the drive amplifier and the transmission power level value output from the AC-DC converter, the difference value and the transmission of the corresponding channel stored in the memory unit Comparing a power control reference value to determine a drive amplifier compensation value, and generates a control signal based on the compensation value to adjust the gain of the drive amplifier by controlling the terminal control unit for compensating and output the RF transmission power output from the duplexer RF transmission power compensation device in a mobile communication terminal comprising a. The method of claim 1, The AC-DC converter is an RF transmission power compensation device for a mobile communication terminal, characterized in that implemented in the DC rectifier circuit consisting of a diode, a resistor and a capacitor to convert the RF transmission signal output from the duplexer to a DC signal. Storing, in the memory, a transmission power control reference value for each channel corresponding to a difference between the AGC signal level of the driving amplifier and the transmission power level of the duplexer measured at room temperature in order to compensate for RF transmission power in the mobile communication terminal; Outputting an AGC signal corresponding to the control signal to the terminal controller in a driving amplifier for amplifying the RF transmission signal according to the control signal in an arbitrary channel and temperature environment and outputting the RF signal to the power amplifier; Converting an RF transmission signal output from a duplexer into a DC signal through the power amplifier and outputting a corresponding transmission power level value to the terminal controller; After calculating a difference value between the AGC signal level value output from the driving amplifier and the transmission power level value, and comparing the difference value and the transmission power control reference value stored in the memory to amplify or attenuate the RF transmission power. Determining a compensation value; And generating a new control signal based on the compensation value determined above, and adjusting the gain of the driving amplifier to compensate for and output the RF transmission power output from the duplexer. Power compensation method. The method of claim 3, wherein The transmission power level value input to the terminal controller is a power level value corresponding to an RF transmission signal output through a power amplifier and a duplexer which are sensitive to temperature change, and is different from each other according to each channel and temperature change used in the terminal. RF transmission power compensation method in a mobile communication terminal, characterized in that the input is a different transmission power level value. The method of claim 3, wherein The process of compensating and outputting the RF transmission power includes lower transmission power level values at room temperature when the mobile communication terminal uses a channel of a low frequency band in a low temperature environment or a channel of a high frequency band in a high temperature environment. The difference between the AGC signal level and the transmission power level value is calculated as a value smaller than the transmission power control reference value stored in the memory, thereby determining a predetermined amplification compensation value and increasing the gain of the driving amplifier. And amplifying and amplifying the RF transmission power output from the duplexer by using the same RF transmission power as at room temperature. The method of claim 3, wherein The process of compensating and outputting the RF transmit power includes a higher transmit power level at room temperature when the mobile communication terminal uses a channel of a high frequency band in a low temperature environment or a channel of a low frequency band in a high temperature environment. The difference between the AGC signal level and the transmission power level value is calculated as a value larger than the transmission power control reference value stored in the memory, thereby determining a predetermined attenuation compensation value to increase the gain of the driving amplifier. And attenuating the RF transmission power output from the duplexer by attenuating the RF transmission power at the same temperature as the normal temperature to attenuate the RF transmission power.

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