KR20060029423A - Mobile station having pam drive voltage changed function and method thereof - Google Patents

Abstract

The present invention relates to a mobile communication terminal having a PAM driving voltage variable function and a control method thereof. According to the present invention, the output power level of the PAM is linearly subdivided to set the PAM available driving voltage in consideration of the linear margin for each subdivided power step; Setting a PDM signal value in the MSM that matches one-to-one with a Tx AGC table value referred to according to the transmission power to apply the optimal driving voltage set according to the transmission power of the PAM; Applying a transmission control signal to an RFT in an MSM with reference to the Tx AGC table according to a received power level received from a base station; Referring to the transmission control signal, a one-to-one matched PDM signal value is applied from the MSM to the variable control signal of the DC / DC converter, and the output voltage of the DC / DC converter is variable to drive the PAM at an optimum voltage. Therefore, by applying a DC / DC converter as the driving voltage source (Vcc) of the PAM, the PAM driving voltage is varied according to the PAM output voltage level, thereby increasing the efficiency of the PAM, lowering power consumption, and also generating energy as heat by the increased efficiency. It is possible to reduce the heat generation by reducing the power consumption, it is possible to increase the use time of the battery by less power consumption.

PAM, Voltage, Variable, Mobile Communication, Output, Power, Level, Transmit, PWM

Description

Mobile communication terminal with variable drive voltage and its control method {MOBILE STATION HAVING PAM DRIVE VOLTAGE CHANGED FUNCTION AND METHOD THEREOF}

1 is a block diagram showing the main part of a conventional PAM driving voltage type mobile communication terminal.

2 shows a TxAGC table of RAS RAM.

Figure 3 is a block diagram showing a mobile communication terminal having a PAM drive voltage variable function and a control method according to the present invention.

4 is a view showing a power consumption improvement rate according to the present invention.

<Description of Symbols for Main Parts of Drawings>

110: battery 120: DC / DC converter

130: PAM 140: Duplexer

150: RFT 160: MSM

The present invention relates to a PAM driving voltage type mobile terminal and a control method thereof, and more particularly, a mobile terminal having a PAM driving voltage variable function using a DC / DC converter as a driving voltage source (Vcc) of a power amplifier module (PAM). A communication terminal and a control method thereof.

1 is a block diagram illustrating a main part of a conventional PAM driving voltage type mobile communication terminal, and FIG. 2 is a diagram illustrating a TxAGC table of a RAS RAM.

As shown in the drawing, the conventional PAM driving voltage type mobile communication terminal supplies a voltage of the battery 10 to a driving voltage Vcc of the PAM 30 using a load switch 20. .

The PAM driving voltage supply method uses two Tx AGC tables of RAS RAM for each power mode (High, Low) of the PAM 30 (see FIG. 2).

That is, in the conventional PAM driving, the voltage of the battery 10 (approximately 4.2 to 3.0V) is supplied to the driving voltage (Vcc) of the PAM 30 using the load switch 20, but MSM (Mobile Station Modem) ( According to the PA_R0 signal of 60, the operation mode of the PAM 60 is divided into two modes of high power (28 to 16 dBm) and low power (16 to 55 dBm).

As shown in FIG. 2, of the two Tx AGC tables of the RAS RAM for each operation mode (High and Low) of the PAM 30, when the MSM 60 operates in the high power mode, the MSM 60 refers to the region 1 of the table 1 in the RFT. The tx_agc_adj signal (values of 0 to 511) is sent to (50). When operating in the low power mode, the tx_agc_adj signal is sent with reference to the ② area of Table 4. At this time, the driving voltage Vcc of the PAM 60 is driven by the voltage of the battery 10 (4.2 to 3.0V) without variation for each operation mode.

However, since the conventional PAM driving voltage type mobile communication terminal selects / controls the power mode by only two operation modes of the high power mode and the low power mode for each output power level of the PAM, the PAM according to the transmission power level. There was a problem that can not be controlled and controlled to the optimum voltage.

Accordingly, the present invention has been made to solve the above-described problems, PAM driving voltage to apply a DC / DC converter to the driving voltage source (Vcc) of the PAM to vary the PAM driving voltage according to the PAM output voltage level An object of the present invention is to provide a mobile communication terminal having a variable function and a control method thereof.

A mobile communication terminal having a variable PAM driving voltage function according to the present invention for achieving the above object, in the mobile communication terminal having a variable PAM driving voltage function, by linearly subdividing the output power level of the PAM, Set the PAM available driving voltage considering linear margin for each subdivided power level, set PDM signal value matching one-to-one to Tx AGC table value which is referred to according to the transmission power, and according to the received power level received from the base station. An MSM for outputting a transmission control signal to the FRT by referring to the Tx AGC table and applying a one-to-one matched PDM signal value from the MSM to the variable control signal of the DC / DC converter; Supplying a driving voltage of the battery to the PAM by PWM control, the output voltage is variable by the variable control signal of the MSM characterized in that it comprises a DC / DC converter for driving the PAM at the optimum voltage.

In addition, the control method of a mobile communication terminal having a variable PAM driving voltage function according to the present invention, in the control method of a mobile communication terminal having a variable PAM driving voltage function, by linearly subdividing the output power level of the PAM, Setting a PAM available driving voltage in consideration of a linear margin for each of the granular power stages; Setting a PDM signal value in the MSM that has a one-to-one correspondence with a Tx AGC table value referred to according to the transmission power to apply the optimal driving voltage set according to the transmission power of the PAM; Applying a transmission control signal to an RFT in an MSM by referring to the Tx AGC table according to a received power level received from a base station; Applying a one-to-one matched PDM signal value to the variable control signal of the DC / DC converter in the MSM by referring to the transmission control signal, and driving the PAM at an optimal voltage by varying the output voltage of the DC / DC converter. It is done.

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

3 is a block diagram illustrating a mobile communication terminal having a variable PAM driving voltage function and a control method thereof according to the present invention, and FIG. 4 is a diagram illustrating a power consumption improvement rate according to the present invention.

As shown, the present invention includes a battery 110, a DC / DC converter 120, a PAM 130, a duplexer 140, an RFT 150, and an MSM 160.

The MSM 160 is a device having a central processing function similar to a central processing unit (CPU) of a computer, and the MSM plays a most important role in a mobile phone. The duplexer 100 communicates with a base station through an antenna.

The PAM 130 uses the output voltage of the DC / DC converter 120 as the driving voltage Vcc to drive the optimum voltage in consideration of efficiency, and to vary the output voltage of the DC / DC converter 120. The MSM 160 inputs a variable control signal (Ref. IN).

According to the PA_R0 signal of the MSM 160, the operation mode of the PAM 130 is divided into two modes of high power (28-16 dBm) and low power (16-55 dBm).

When operating in the high power mode of 28 to 16 dBm using both Tx AGC tables of the RAS RAM shown in FIG. 2, the MSM 160 transmits the RFT 150 to the RFT 150 with reference to the region 1 of Table 1. (tx_agc_adj) is transmitted, and at this time, a PDM control signal that is matched one-to-one is transmitted to the variable control signal (Ref. IN) of the DC / DC converter 120.

On the other hand, when operating in the low level mode of the 16 ~ -55dBm range, the transmission control signal (tx_agc_adj) is sent with reference to the ② area of Table 2, and in the same principle as above, the MSM 160 converts the PDM control signal to the DC / DC converter. A variable control signal (Ref. IN) of 120 is sent.

Referring to the operation of the present invention configured in this way in more detail as follows.

First, the output power level (about 28 to -50 dBm) of the PAM 160 is linearly subdivided to set the PAM available driving voltage considering the linear margin (Linearity Margin) for each subdivided power step.

Thereafter, as a method for applying the optimal driving voltage set above according to the transmission power (Tx Power) of the PAM 130, two Tx AGC table values of the RAS RAM referred to according to the transmission power (that is, tx agc adj PDM signal value that is matched one-to-one (value) to the MSM 160 (see FIG. 2).

Subsequently, RFT transmits a transmission control signal tx agc adj in the MSM 160 with reference to one of the two Tx AGC tables shown in FIG. 2 according to a received power level (Rx Power Level) received from a base station (not shown). To 150.

In this case, the one-to-one matched PDM signal value is applied from the MSM 160 to the variable control signal Ref. IN of the DC / DC converter 120 with reference to the transmission control signal tx agc adj.

Accordingly, the output voltage PAM Vcc of the DC / DC converter 120 is varied according to the variable control signal Ref. IN to drive the PAM 130 at an optimum voltage.

Although the above has been illustrated and described with respect to the preferred embodiments of the present invention, the present invention is not limited to the above-described embodiments, the present invention without departing from the gist of the invention claimed in the claims Anyone with a variety of variations will be possible.

As described above, according to the mobile communication terminal having the PAM driving voltage variable function and the control method thereof, the PAM driving voltage is applied according to the PAM output voltage level by applying a DC / DC converter as the driving voltage source (Vcc) of the PAM. By varying the efficiency of the PAM, the power consumption can be increased, the power consumption can be lowered, and the energy generated by the heat can be reduced by the increased efficiency, thereby reducing the heat generation. have.

Claims (2)

In the mobile communication terminal having a PAM drive voltage variable function, Linearly subdivid the output power level of the PAM to set the PAM available drive voltage considering the linear margin for each subdivided power step, and PDM signal matching one-to-one to the Tx AGC table value referenced according to the transmission power Setting a value, outputting a transmission control signal to the FRT by referring to the Tx AGC table according to the received power level received from the base station, and applying a one-to-one matched PDM signal value from the MSM to the variable control signal of the DC / DC converter. MSM; Supplying a driving voltage of the battery to the PAM by PWM control, the output voltage is changed by the variable control signal of the MSM PAM driving voltage, characterized in that it comprises a DC / DC converter for driving the PAM at an optimal voltage Mobile communication terminal having a variable function. In the control method of a mobile communication terminal having a variable PAM driving voltage, Linearly subdividing the output power level of the PAM to set the PAM available driving voltage in consideration of the linear margin for each subdivided power step; Setting a PDM signal value in the MSM that has a one-to-one correspondence with a Tx AGC table value referred to according to the transmission power to apply the optimal driving voltage set according to the transmission power of the PAM; Applying a transmission control signal to an RFT in an MSM by referring to the Tx AGC table according to a received power level received from a base station; Applying a one-to-one matched PDM signal value to the variable control signal of the DC / DC converter in the MSM by referring to the transmission control signal, and driving the PAM at an optimal voltage by varying the output voltage of the DC / DC converter. A control method of a mobile communication terminal having a variable PAM driving voltage function.

Images