KR20010099544A - Device for controlling transmission power backward in cdma mobile communication phone - Google Patents

Abstract

By adding a simple switch circuit to the transmitter of the CDMA mobile communication terminal, and more specifically, the transmitter of the mobile station, it is possible to perform reverse power control without driving a driving amplifier or a power amplifier in a general strong or medium electric field region. The present invention relates to a reverse power control device in a CDA mobile communication terminal that can significantly increase battery life. According to the reverse power control device in a CDA mobile communication terminal according to the present invention, a simple switch circuit is added to a transmitting end of a mobile station. In addition, the system can perform reverse power control without driving a driving amplifier or power amplifier in a general strong electric field or a medium electric field, thereby greatly improving the battery usage time, and providing a minimum transmission power requirement in IS-98 that defines a minimum mobile station standard. It allows the line to satisfy the transmission conductive spurious emissions regulations have a superior effect.

Description

DEVICE FOR CONTROLLING TRANSMISSION POWER BACKWARD IN CDMA MOBILE COMMUNICATION PHONE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reverse power control apparatus in a mobile communication terminal (CD Division Multiple Access (CDMA)). More particularly, a simple switch circuit is added to a transmitting end of a mobile station in a general strong electric field or a medium electric field region. The present invention relates to a reverse power control device in a CDA mobile communication terminal which allows a battery to be used for a long time by performing reverse power control without driving a driving amplifier or a power amplifier.

In the conventional CDMA mobile communication terminal, the reverse power control apparatus detects a reception level of a radio frequency (RF) signal as shown in FIG. 1 and then corresponds to an intermediate frequency (IF). MSM (Mobile Station Manager; hereinafter referred to as MSM) for outputting an automatic gain control signal; A modulator (2) for receiving an IF signal from the MSM (1) and modulating the IF signal; An IF automatic gain controller (AGC) 3 for adjusting the gain of the IF signal according to the level of the IF automatic gain control signal output from the MSM 1; An up-mixer 4 for receiving an IF signal from the IF auto gain controller 3 and converting the IF signal into an RF signal; A driver amplifier (AMP) for receiving an RF signal from the up-mixer 4 and amplifying and outputting the RF signal; And a power amplifier 6 that receives the RF signal from the driving amplifier 5, amplifies the RF signal by the transmission power, and outputs the same to the duplexer 7.

In general, the aforementioned reverse power control apparatus in the conventional CDMA mobile communication terminal performs only 80 dBm dynamic range by varying only the gain of the IF auto gain controller when controlling the reverse power of the RF signal.

However, the method of controlling gain of the conventional transmitter-side IF automatic gain controller as described above can only satisfy the transmitter-side dynamic range (maximum power 23-30dBm, minimum power -50dBm or less: total 80dBm), but sufficient margin is sufficient. There is a problem that unnecessary power loss occurs because it does not have.

In addition, as a method for controlling gain of the conventional transmitter-side IF automatic gain controller as described above, the transmission conductivity spurious emission specification (-42dBc / 30KHz ± 900KHz to ± 1.98MHz, -54dBc when the transmission power is -13dBm / 1.23MHz) /30KHz±1.98MHz or more) also can be satisfied just like the above-mentioned dynamic range of the transmission side, but there is a problem that unnecessary power loss occurs because it does not have enough margin.

In this case, the above-described problem occurs because the sum of the fixed gain of the transmission driver and the power amplifier is too large, and the noise floor and the spurious generated in the path are too large at the terminal.

Therefore, the high gain characteristics of the power amplifier, which is the final stage amplifier, and the nonlinear characteristics of the amplifier, increase the current consumption and decrease the efficiency of the RF transmission stage, thereby increasing battery consumption and shortening the talk time of the terminal. Will occur.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to sufficiently satisfy the minimum transmission power specification and the transmission conductivity spurious emission regulation of IS-98, which define the minimum mobile station standard. The present invention provides a reverse power control apparatus for a CDA mobile communication terminal.

Another purpose is to add a simple switch circuit to the transmitting end of the mobile station, allowing the CDMA to significantly improve battery life by allowing reverse power control without driving or power amplifiers in a typical high or medium electric field region. The present invention provides a reverse power control apparatus in a communication terminal.

In order to achieve the above object, a reverse power control apparatus in a CDA mobile communication terminal according to an embodiment of the present invention includes a modulator for receiving and modulating an IF signal from a transmitting front end block, and outputting the modulated IF signal. After receiving the IF signal from the modulator after determining the IF automatic gain control to automatically adjust the gain of the IF signal to correspond to the determined IF transmission gain, the IF automatic gain control unit receives the IF signal and converts it into an RF signal An up-mixer, a drive amplifier that receives and amplifies an RF signal from the up-mixer, and outputs the amplified RF signal from the bandpass filter and amplifies the RF signal by a transmission power and outputs the duplexer to the duplexer In the reverse power control device in a CDMA mobile communication terminal having an amplifier,

After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and the calculated reverse power (dBm) is a value suitable for bypassing the driving amplifier. If it is determined whether or not it is a proper value, a bypass switching control signal is output and a correction value in consideration of the calculated reverse power (dBm) and the gain (dB) of the driving amplifier is calculated based on the calculated transmission power of the IF auto gain controller. On the other hand, if the calculated reverse power (dBm) is not suitable for bypassing the driving amplifier, the output power of the driving amplifier passes the switching control signal and the transmission gain of the IF auto gain control unit is calculated. MSM to adjust the gain value considering only the power (dBm); And

And a first switch mounted at a signal input terminal of the driving amplifier and a second switch mounted at a signal output terminal of the driving amplifier, and receiving an bypass switching control signal from the MSM, outputting the RF signal output from the up-mixer. Designates a path so that the signal is bypassed without passing through the driving amplifier, and when the switching control signal for driving the amplifier passes through the MSM, the RF signal output from the up-mixer passes the driving amplifier normally. It is characterized by consisting of a switch unit.

In addition, the apparatus for reverse power control in a CDA mobile communication terminal according to this embodiment of the present invention includes a modulator for receiving and outputting an IF signal from a transmitting front end block and outputting the modulated IF signal from the modulator after the IF transmission gain is determined. An IF auto gain control unit that automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain upon receiving an IF signal; an up-mixer that receives an IF signal from the IF auto gain control unit and converts it into an RF signal; -A CDM move having a drive amplifier that receives an RF signal from a mixer, amplifies and outputs it, and a power amplifier that receives the RF signal from the bandpass filter, amplifies the RF signal by the transmission power, and then outputs the duplexer. In the reverse power control apparatus in a communication terminal,

After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and the calculated reverse power (dBm) is a value suitable for bypassing the power amplifier. If it is appropriate, the output value of the bypass switching control signal is outputted and the transmission gain of the IF automatic gain control unit is a correction value considering the calculated reverse power (dBm) and gain (dB) of the power amplifier. On the other hand, if the calculated reverse power (dBm) is not suitable for bypassing the power amplifier, the output power of the power amplifier pass-through switching control signal is outputted and the calculated gain of the IF auto gain control unit is transmitted. MSM adjusting to gain value considering only (dBm); And

And a first switch mounted at the signal input terminal of the power amplifier and a second switch mounted at the signal output terminal of the power amplifier. When the bypass switching control signal is received from the MSM, the RF signal output from the driving amplifier is output. A path is specified to be bypassed without passing through the power amplifier, and when a switching control signal for passing a power amplifier is received from the MSM, the switch is configured to specify a path so that the RF signal output from the driving amplifier normally passes through the power amplifier. Characterized in that configured.

On the other hand, in the CDMA mobile communication terminal according to an embodiment of the present invention, the reverse power control device is a modulator for receiving and modulating the IF signal from the transmitting front-end block, and outputs, and after the IF transmission gain is determined from the modulator An IF auto gain control unit that automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain upon receiving an IF signal; an up-mixer that receives an IF signal from the IF auto gain control unit and converts it into an RF signal; -A CDM move having a drive amplifier that receives an RF signal from a mixer, amplifies and outputs it, and a power amplifier that receives the RF signal from the bandpass filter, amplifies the RF signal by the transmission power, and then outputs the duplexer. In the reverse power control apparatus in a communication terminal,

After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and then the IF automatic gain control unit corresponds to the calculated reverse power value (dBm). An MSM that adjusts the IF transmit gain and outputs its reverse power value in dBm; And

After receiving the reverse power value (dBm) from the MSM characterized in that the drive amplifier gain control unit for adjusting the gain of the drive amplifier to correspond to the reverse power value (dBm).

1 is a functional block diagram showing the configuration of a reverse power control apparatus in a conventional CDMA mobile communication terminal;

2 is a functional block diagram showing a configuration of a reverse power control apparatus in a CDA mobile communication terminal according to an embodiment of the present invention;

3 is a functional block diagram showing the configuration of a reverse power control apparatus in a CDA mobile communication terminal according to this embodiment of the present invention;

4 is a functional block diagram showing the configuration of a reverse power control apparatus in a CDA mobile communication terminal according to a third embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: first MSM 120: first switch

121: first switch 122: second switch

130: first modulator 140: first IF auto gain controller

150: first up-mixer 160: first drive amplifier

170: first power amplifier 180: first duplexer

210: 2nd MSM 220: 2nd switch part

221: first switch 222: second switch

230: second modulator 240: second IF auto gain controller

250: second up-mixer 260: second drive amplifier

270: second power amplifier 280: second duplexer

310: third MSM 320: drive amplifier gain control unit

330: third modulator 340: third IF auto gain controller

350: third up-mixer 360: third drive amplifier

370: third power amplifier 380: third duplexer

Hereinafter, a reverse power control apparatus in a CDA mobile communication terminal according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a functional block diagram of a reverse power control apparatus in a CDA mobile communication terminal according to an embodiment of the present invention. The reverse power control apparatus in a CDMA mobile communication terminal according to an embodiment of the present invention may include a first MSM ( 110, a first switch unit 120 including a first switch 121 and a second switch 122, a first modulator 130, a first IF automatic gain controller 140, and a first up-mixer ( 150, a first driving amplifier 160, and a first power amplifier 170.

After receiving the power control bit transmitted from the base station, the first MSM 110 determines the reverse power (dBm) of the RF transmission signal to correspond to the power control bit, and the calculated reverse power (dBm) is determined by the first power control bit. The first switch 121 and the second switch mounted in the first switch unit 120 may be configured to determine whether the first driving amplifier 160 is a value suitable for bypassing the driving amplifier 160. And outputting an automatic gain control signal considering the calculated reverse power (dBm) and the gain (dB) of the first driving amplifier 160 to the first IF automatic gain controller 140 at the same time. On the other hand, if the calculated reverse power (dBm) is an unsuitable value for bypassing the first driving amplifier 160, the first switch mounted in the first switch unit 120 receives a switching control signal for driving a driving amplifier ( 121) and output to second switch 122 And at the same time it serves to output an automatic gain control signal considering only the calculated reverse power (dBm) of claim 1 in the IF automatic gain control unit 140.

In addition, the first switch unit 120 may include a first switch 121 mounted at a signal input terminal of the first driving amplifier 160 and a second switch mounted at a signal output terminal of the first driving amplifier 160. 122), when the bypass switching control signal is input from the first MSM 110, the RF signal output from the first up-mixer 150 does not go through the first driving amplifier 160. While the path is specified to pass, when the switching control signal for driving the amplifier passes from the first MSM 110, the RF signal output from the first up-mixer 150 is applied to the first driving amplifier 160. It is responsible for specifying the path to pass normally.

Meanwhile, the first modulator 130 receives the IF signal from the transmitting front end block, modulates the IF signal, and outputs the modulated signal to the first IF auto gain controller 140.

In addition, when the IF transmission gain is determined by the auto gain control signal output from the first MSM 110, the first IF auto gain controller 140 receives an IF signal from the first modulator 130. The gain of the IF signal is automatically adjusted to correspond to the determined IF transmission gain, and then output to the first up-mixer 150.

Meanwhile, when the RF transmission path is designated as the first driving amplifier 160 bypass through the first switch unit 120, the first up-mixer 150 may turn off the first IF auto gain control unit 140. After receiving the output IF signal is converted into an RF signal and outputs to the first power amplifier 170, while the RF transmission path through the first switch unit 120 passes the first drive amplifier 160 If it is designated as and receives the IF signal output from the first IF automatic gain control unit 140 converts to an RF signal and serves to output to the first driving amplifier 160.

In addition, when the RF transmission path is designated as the pass path of the first drive amplifier 160 through the first switch unit 120, the first drive amplifier 160 outputs the first up-mixer 150. A RF signal is received and amplified to an appropriate level, and then outputs to the first power amplifier 170.

On the other hand, the first power amplifier 170 outputs from the first up-mixer 150 when the RF transmission path is designated as the bypass of the first driving amplifier 160 through the first switch unit 120. When the RF signal is received and amplified by the transmission power and then output to the first duplexer 180, if the RF transmission path is designated as the pass path of the first driving amplifier 160 through the first switch unit 120, The RF signal output from the first driving amplifier 160 is amplified by the transmission power and then outputs to the first duplexer 180.

Next, an operation process of the reverse power control apparatus in the CDA mobile communication terminal according to an embodiment of the present invention having the above configuration will be described below with reference to FIG. 2.

First, after receiving the power control bit transmitted from the base station, the first MSM 110 calculates the reverse power (dBm) of the RF transmission signal to correspond to the power control bit.

The first MSM 110 may then bypass the first drive amplifier 160 if the calculated reverse power (dBm) is a suitable value to bypass the first drive amplifier 160. It is determined whether the value is inappropriate for.

At this time, if the calculated reverse power (dBm) is a value suitable to bypass the first driving amplifier 160, the first MSM 110 sends a bypass switching control signal to the first switch unit 120. And outputs the gain of the first IF auto gain control unit 140 to the first switch 121 and the second switch 122 mounted therein, and the calculated reverse power (dBm) and the first driving amplifier ( Adjust the gain value in consideration of the gain (dB) of the 160.

Then, the first switch 121 and the second switch 122 mounted in the first switch unit 120 receive the bypass switching control signal output from the first MSM 110, and then, The path is designated such that the RF signal output from the first up-mixer 150 is bypassed without passing through the first driving amplifier 160.

When the gain of the first IF auto gain controller 140 and the path of the first switch unit 120 are designated by the above-described operation, the first modulator 130 receives the IF signal from the front-side block of the transmitter. After receiving and modulating the input, it outputs to the first IF automatic gain control unit 140. Then, the first IF auto gain controller 140 receives the IF signal from the first modulator 130 and automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain, and then the first IF. Output to up-mixer 150. Subsequently, the first up-mixer 150 receives an IF signal output from the first IF auto gain controller 140, converts the IF signal into an RF signal, and outputs the converted RF signal to the first power amplifier 170. Then, the first power amplifier 170 receives the RF signal output from the first up-mixer 150 and amplifies it by the transmission power and outputs the RF signal to the first duplexer 180. Therefore, the RF signal described above does not pass through the first driving amplifier 160.

On the other hand, if the calculated reverse power (dBm) is an inappropriate value for bypassing the first driving amplifier 160, the first MSM 110 is a driving amplifier. Outputs a pass switching control signal to the first switch 121 and the second switch 122 mounted in the first switch unit 120 and calculates the gain of the first IF automatic gain control unit 140 at the same time. Adjust the gain value considering only reversed power (dBm).

Then, the first switch 121 and the second switch 122 mounted in the first switch unit 120 receive the switching control signal for passing the driving amplifier output from the first MSM 110, and then The path is designated such that the RF signal output from the first up-mixer 150 passes normally through the first driving amplifier 160.

When the gain of the first IF auto gain controller 140 and the path of the first switch unit 120 are designated by the above-described operation, the first modulator 130 receives the IF signal from the front-side block of the transmitter. After receiving and modulating the input, it outputs to the first IF automatic gain control unit 140. Then, the first IF auto gain controller 140 receives the IF signal from the first modulator 130 and automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain, and then the first IF. Output to up-mixer 150. Subsequently, the first up-mixer 150 receives the IF signal output from the first IF auto gain controller 140, converts the IF signal into an RF signal, and outputs the converted RF signal to the first driving amplifier 160. Then, the first driving amplifier 160 amplifies the RF signal output from the first up-mixer 150 to an appropriate level and outputs the RF signal to the first power amplifier 170. In addition, the first power amplifier 170 receives the RF signal output from the first driving amplifier 260 and amplifies it by the transmission power and outputs the RF signal to the first duplexer 180. Therefore, the above-described RF signal is to pass through the first driving amplifier 160.

On the other hand, the reverse power control device in the CDA mobile communication terminal according to this embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a functional block diagram of a reverse power control apparatus in a CDA mobile communication terminal according to this embodiment of the present invention. The reverse power control apparatus in a CDMA mobile communication terminal according to this embodiment of the present invention is a second MSM ( 210, a second switch unit 220 including a first switch 221 and a second switch 222, a second modulator 230, a second IF auto gain controller 240, and a second up-mixer ( 250, a second drive amplifier 260, and a second power amplifier 270.

After receiving the power control bit transmitted from the base station, the second MSM 210 determines the reverse power (dBm) of the RF transmission signal to correspond to the power control bit, and the calculated reverse power (dBm) is the second power. 2, the first switch 221 and the second switch mounted in the second switch unit 220 may be configured to determine whether the power amplifier 270 is a value suitable for bypassing the power amplifier 270. And outputs an automatic gain control signal considering the calculated reverse power (dBm) and the gain (dB) of the second power amplifier 270 to the second IF automatic gain control unit 240 at the same time. On the other hand, if the calculated reverse power (dBm) is unsuitable for bypassing the second power amplifier 270, the first switch mounted in the second switch unit 220 for the power amplifier passing switching control signal ( 221 and output to second switch 222 And at the same time it serves to output a second automatic gain control signal considering only the reverse power (dBm) calculated by the IF automatic gain control unit 240.

In addition, the second switch unit 220 may include a first switch 221 mounted at a signal input terminal of the second power amplifier 270 and a second switch mounted at a signal output terminal of the second power amplifier 270. 222, the RF signal output from the second driving amplifier 260 bypasses the second power amplifier 270 when the switching control signal for bypass is input from the second MSM 210. When the path is specified, the RF signal output from the second driving amplifier 260 passes normally through the second power amplifier 270 when the switching control signal for driving the driving amplifier is input from the second MSM 210. It is responsible for specifying paths.

Meanwhile, the second modulator 230 receives an IF signal from the transmitting front end block, modulates the IF signal, and outputs the modulated IF signal to the second IF auto gain controller 240.

The second IF auto gain controller 240 receives an IF signal from the second modulator 230 after the IF transmission gain is determined by the auto gain control signal output from the second MSM 210. It automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain and serves to output to the second up-mixer 250.

Meanwhile, the second up-mixer 250 receives an IF signal output from the second IF auto gain controller 240, converts the IF signal into an RF signal, and outputs the converted RF signal to the second driving amplifier 260. .

In addition, the second driving amplifier 260 outputs from the second up-mixer 250 when the RF transmission path is designated as the second power amplifier 270 bypass through the second switch unit 220. When the RF signal is received and amplified to an appropriate level and output to the second duplexer 280, the RF transmission path is designated as the second power amplifier 270 passing path through the second switch unit 220. The RF signal output from the second up-mixer 250 is input, amplified to an appropriate level, and then output to the second power amplifier 270.

On the other hand, when the RF transmission path is designated as the second power amplifier 270 pass path through the second switch unit 220, the second power amplifier 270 outputs the second drive amplifier 260. The RF signal is received and amplified by the transmission power and then output to the second duplexer 280.

Next, an operation process of the reverse power control apparatus in the CDA mobile communication terminal according to the present embodiment having the above configuration will be described below with reference to FIG. 3.

First, after receiving the power control bit transmitted from the base station, the second MSM 210 calculates the reverse power (dBm) of the RF transmission signal to correspond to the power control bit.

The second MSM 210 may then bypass the second power amplifier 270 if the calculated reverse power (dBm) is a suitable value to bypass the second power amplifier 270. It is determined whether the value is inappropriate for.

At this time, if the calculated reverse power (dBm) is a value suitable to bypass the second power amplifier 270, the second MSM 210 sends a bypass switching control signal to the second switch unit 220. Outputs the first switch 221 and the second switch 222 mounted therein, and simultaneously calculates the gain of the second IF auto gain control unit 240 with the calculated reverse power (dBm) and the second power amplifier ( The gain (dB) of 260 is adjusted to a gain value.

Then, the first switch 221 and the second switch 222 mounted in the second switch unit 220 receive the bypass switching control signal output from the second MSM 210 and then drive the drive. The path is designated such that the RF signal output from the amplifier 260 is bypassed without passing through the second power amplifier 270.

When the gain of the second IF automatic gain control unit 240 and the path of the second switch unit 220 are designated by the above-described operation process, the second modulator 230 receives the IF signal from the front-side block of the transmitter. After receiving and modulating the input, it outputs to the second IF automatic gain control unit 240. Then, the second IF auto gain controller 240 receives the IF signal from the second modulator 230 and automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain, and then the second IF. Output to up-mixer 250. Subsequently, the second up-mixer 250 receives an IF signal output from the second IF auto gain controller 240, converts the IF signal into an RF signal, and outputs the RF signal to the second driving amplifier 260. Then, the driving amplifier 260 receives the RF signal output from the second up-mixer 250 and amplifies the RF signal to an appropriate level and outputs the RF signal to the second duplexer 280. Therefore, the above-described RF signal does not go through the second power amplifier 270.

On the other hand, if the calculated reverse power (dBm) is an inappropriate value for bypassing the second power amplifier 270 as a result of the determination of the second MSM 210 described above, the second MSM 210 is a power amplifier. Outputs a pass switching control signal to the first switch 221 and the second switch 222 mounted in the second switch unit 220 and simultaneously calculates the gain of the second IF automatic gain control unit 240. Adjust the gain value considering only reversed power (dBm).

Then, the first switch 221 and the second switch 222 mounted in the second switch unit 220 receives the switching control signal for passing the power amplifier output from the second MSM 210, and then The path is designated such that the RF signal output from the driving amplifier 260 passes normally through the second power amplifier 270.

When the gain of the second IF automatic gain control unit 240 and the path of the second switch unit 220 are designated by the above-described operation process, the second modulator 230 receives the IF signal from the front-side block of the transmitter. After receiving and modulating the input, it outputs to the second IF automatic gain control unit 240. Then, the second IF auto gain controller 240 receives the IF signal from the second modulator 230 and automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain, and then the second IF. Output to up-mixer 250. Subsequently, the second up-mixer 250 receives an IF signal output from the second IF auto gain controller 240, converts the IF signal into an RF signal, and outputs the RF signal to the second driving amplifier 260. Then, the second driving amplifier 260 amplifies the RF signal output from the second up-mixer 250 to an appropriate level and outputs the RF signal to the second power amplifier 270. In addition, the second power amplifier 270 receives the RF signal output from the second driving amplifier 260 and amplifies as much as the transmission power and outputs the RF signal to the second duplexer 280. Therefore, the above-described RF signal is to pass through the second power amplifier 270.

Meanwhile, a reverse power control apparatus in a CDA mobile communication terminal according to a third embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 4 is a functional block diagram of a reverse power control apparatus in a CDA mobile communication terminal according to a third embodiment of the present invention. The reverse power control apparatus in a CDMA mobile communication terminal according to the third embodiment of the present invention is a third MSM ( 310, the drive amplifier gain control unit 320, the third modulator 330, the third IF auto gain control unit 340, the third up-mixer 350, the third drive amplifier 360, and the third power It consists of an amplifier 370.

After receiving the power control bit transmitted from the base station, the third MSM 310 determines the reverse power (dBm) of the RF transmission signal to correspond to the power control bit, and then calculates the reverse power value (dBm). Correspondingly, an auto gain control signal is output to the third IF auto gain control unit 340, and the calculated reverse power value dBm is output to the third driving amplifier 360.

In addition, the drive amplifier gain control unit 320 receives the reverse power value (dBm) from the third MSM 310 and then adjusts the gain of the third drive amplifier 360 to correspond to the reverse power value (dBm). It plays a role in controlling.

Meanwhile, the third modulator 330 receives an IF signal from the transmitting front end block, modulates the IF signal, and outputs the modulated signal to the third IF auto gain controller 340.

In addition, when the third IF auto gain control unit 340 receives an IF signal from the third modulator 330 after the IF transmission gain is determined by the auto gain control signal output from the third MSM 310, The gain of the IF signal is automatically adjusted to correspond to the determined IF transmission gain, and then output to the third up-mixer 350.

Meanwhile, the third up-mixer 350 receives an IF signal output from the third IF auto gain controller 340, converts the IF signal into an RF signal, and outputs the RF signal to the third driving amplifier 360. .

In addition, when the third driving amplifier 360 receives an RF signal from the third up-mixer 350 after the gain is adjusted by the driving amplifier gain control unit 320, the third driving amplifier 360 may convert the RF signal into a reverse power value ( After amplifying to an appropriate level corresponding to dBm) and outputs to the third power amplifier (370).

Meanwhile, the third power amplifier 370 receives an RF signal output from the third driving amplifier 360, amplifies the transmission power by the transmission power, and outputs the RF signal to the third duplexer 380.

Next, the operation of the reverse power control apparatus in the CDA mobile communication terminal according to the third embodiment of the present invention having the above-described configuration will be described with reference to FIG. 4.

First, after receiving the power control bit transmitted from the base station, the third MSM 310 calculates the reverse power (dBm) of the RF transmission signal to correspond to the power control bit.

Thereafter, the third MSM 310 outputs an auto gain control signal to the third IF auto gain control unit 340 so as to correspond to the calculated reverse power value dBm, while the calculated reverse power value ( dBm) is output to the third driving amplifier 360.

Then, the third IF auto gain control unit 340 adjusts the IF transmission gain by the auto gain control signal output from the third MSM 310.

Meanwhile, the driving amplifier gain control unit 320 receives the reverse power value dBm from the third MSM 310 and then adjusts the gain of the third drive amplifier 360 to correspond to the reverse power value dBm. Adjust

When the gains of the third IF auto gain controller 340 and the third driving amplifier 360 are adjusted by the above-described operation process, the third modulator 330 receives an IF signal from the front-side block of the transmitter. After the modulation is output to the third IF automatic gain control unit 340. Then, the third IF auto gain controller 340 receives the IF signal from the third modulator 330 and automatically adjusts the gain of the IF signal to correspond to the determined IF transmission gain, and then the third IF. Output to the up-mixer 350. Subsequently, the third up-mixer 350 receives the IF signal output from the third IF auto gain controller 340, converts the IF signal into an RF signal, and outputs the converted RF signal to the third driving amplifier 360. Then, the third driving amplifier 360 receives the RF signal output from the third up-mixer 350, amplifies the RF signal to an appropriate level, and outputs the RF signal to the third power amplifier 370. In addition, the third power amplifier 370 receives the RF signal output from the third driving amplifier 360, amplifies the transmission power by the transmission power, and outputs the RF signal to the third duplexer 380. Therefore, the transmission power of the above-described RF signal is to be dually controlled by the third IF automatic gain control unit 340 and the third driving amplifier 360.

As described above, according to the reverse power control apparatus in a CDA mobile communication terminal according to the present invention, a simple switch circuit is added to a transmitting end of a mobile station to reverse power without driving a driving amplifier or a power amplifier in a general strong or medium electric field region. Not only does this significantly increase battery life, but it also has the effect of fully satisfying the minimum transmission power requirements and transmission conductivity spurious emission regulations of the IS-98, which define the minimum mobile station specifications.

Claims (3)

A modulator that receives and modulates an IF signal from a transmitting front end block and outputs the IF signal, and if the IF signal is received from the modulator after the IF transmission gain is determined, the gain of the IF signal is automatically adjusted to correspond to the determined IF transmission gain. An IF auto gain control unit, an up-mixer that receives an IF signal from the IF auto gain control unit and converts it into an RF signal, a driving amplifier that receives and amplifies and outputs an RF signal from the up-mixer, and the bandpass filter In the reverse power control apparatus in a CDM mobile communication terminal having a power amplifier receiving an RF signal and amplifying the RF signal by a transmission power and outputting the same to a duplexer, After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and the calculated reverse power (dBm) is a value suitable for bypassing the driving amplifier. If it is determined whether or not it is a proper value, a bypass switching control signal is output and a correction value in consideration of the calculated reverse power (dBm) and the gain (dB) of the driving amplifier is calculated based on the calculated transmission power of the IF auto gain controller. On the other hand, if the calculated reverse power (dBm) is not suitable for bypassing the driving amplifier, the output power of the driving amplifier passes the switching control signal and the transmission gain of the IF auto gain control unit is calculated. MSM to adjust the gain value considering only the power (dBm); And And a first switch mounted at a signal input terminal of the driving amplifier and a second switch mounted at a signal output terminal of the driving amplifier, and receiving an bypass switching control signal from the MSM, outputting the RF signal output from the up-mixer. Designates a path so that the signal is bypassed without passing through the driving amplifier, and when the switching control signal for driving the amplifier passes through the MSM, the RF signal output from the up-mixer passes the driving amplifier normally. Reverse power control device for a CDM mobile communication terminal, characterized in that the switch unit. A modulator that receives and modulates an IF signal from a transmitting front end block and outputs the IF signal, and if the IF signal is received from the modulator after the IF transmission gain is determined, the gain of the IF signal is automatically adjusted to correspond to the determined IF transmission gain. An IF auto gain control unit, an up-mixer that receives an IF signal from the IF auto gain control unit and converts it into an RF signal, a driving amplifier that receives and amplifies and outputs an RF signal from the up-mixer, and the bandpass filter In the reverse power control apparatus in a CDM mobile communication terminal having a power amplifier receiving an RF signal and amplifying the RF signal by a transmission power and outputting the same to a duplexer, After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and the calculated reverse power (dBm) is a value suitable for bypassing the power amplifier. If it is appropriate to judge whether or not it is a suitable value, it outputs a switching control signal for bypass and the correction value which considers the calculated transmission power (dBm) and gain (dB) of the power gain of the IF automatic gain controller. On the other hand, if the calculated reverse power (dBm) is not suitable for bypassing the power amplifier, the power amplifier passes the switching control signal and passes the transmission gain of the IF auto gain control unit. MSM to adjust the gain value considering only the power (dBm); And And a first switch mounted at the signal input terminal of the power amplifier and a second switch mounted at the signal output terminal of the power amplifier. When the bypass switching control signal is received from the MSM, the RF signal output from the driving amplifier is output. A path is specified to be bypassed without passing through the power amplifier, and when a switching control signal for passing a power amplifier is received from the MSM, the switch is configured to specify a path so that the RF signal output from the driving amplifier normally passes through the power amplifier. A reverse power control apparatus for a CDM mobile communication terminal, characterized in that. A modulator that receives and modulates an IF signal from a transmitting front end block and outputs the IF signal, and if the IF signal is received from the modulator after the IF transmission gain is determined, the gain of the IF signal is automatically adjusted to correspond to the determined IF transmission gain. An IF auto gain control unit, an up-mixer that receives an IF signal from the IF auto gain control unit and converts it into an RF signal, a driving amplifier that receives and amplifies and outputs an RF signal from the up-mixer, and the bandpass filter In the reverse power control apparatus in a CDM mobile communication terminal having a power amplifier receiving an RF signal and amplifying the RF signal by a transmission power and outputting the same to a duplexer, After receiving the power control bit transmitted from the base station, the reverse power (dBm) of the RF transmission signal is determined to correspond to the power control bit, and then the IF automatic gain control unit corresponds to the calculated reverse power value (dBm). An MSM that adjusts the IF transmit gain and outputs its reverse power value in dBm; And And a drive amplifier gain control unit configured to receive a reverse power value (dBm) from the MSM and adjust a gain of the drive amplifier to correspond to the reverse power value (dBm). Device.