KR100600990B1 - Apparatus of Sending Signals in the Mobile Communication Terminal - Google Patents

Abstract

The present invention relates to a transmission apparatus in a mobile communication terminal to improve the efficiency of the output power at the transmitting end of the mobile communication terminal, comprising: a power amplifier for amplifying a power level of a transmission signal and transmitting it through an antenna; A high power detector for detecting a PDM (Pulse Division Modulation) level value by determining a power level read from the power amplifier within a voltage range; A mobile station modem (MSM) for controlling gain by applying a signal size suitable for each level based on the PDM level value recognized by the high power detector; A demodulator for amplifying a transmission signal into a demodulation waveform according to the gain control of the MSM; A small signal amplifier for amplifying the small signal applied from the demodulator; And a band pass filter (BPF) for filtering the signal applied from the small signal amplifier only to a desired frequency band and delivering the signal to the power amplifier, thereby improving the transmission stage output and lowering the gain of the power amplifier. This extends the life of the battery, reducing cost and increasing call and standby time.

Description

Apparatus of Sending Signals in the Mobile Communication Terminal}             

1 is a block diagram showing a transmission device in a mobile communication terminal according to an embodiment of the present invention.

2 is a block diagram showing a transmission device in a mobile communication terminal according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

11, 21: MSM (Mobile Station Mode)

12, 22: demodulator

13, 24: small signal amplifier

14, 23: BPF (Band Pass Filter)

15, 25: Power Amp

16, 26: High Power Detecter

17, 27: Duplexer

18, 28: Diplexer

The present invention relates to a transmitting apparatus in a mobile communication terminal, and more particularly to a transmitting apparatus in a mobile communication terminal to improve the efficiency of the output power in the transmitting end of the mobile communication terminal.

In general, in a transmitting end of a code division multiple access (CDMA) terminal, a signal of a CDMA waveform passing through a demodulator is directly filtered through a BPF, and then the filtered signal is amplified and transmitted through a power amplifier.

However, in a weak electric field situation, the demodulator outputs a demodulator gain 'high' via an MSM based on the output level of the power detector, and the output signal is passed through the BPF. It is input to the amplifier.

At this time, due to the loss (for example, about 4 to 5 (dBm)) generated at the rear end of the power amplifier, the corresponding final output is a specification of the adjacent channel noise, which is an electrical characteristic desired by the developer or operator. If it is satisfied, the actual output is about 24 to 25 (dBm), and if the output of the power amplifier is further increased, the demodulator gain is maximized. The property will not be satisfied.

For this reason, in the prior art, the transmitting end of the CDMA terminal outputs the maximum demodulator gain when the gain of the power amplifier in the area mainly used in the actual field situation is outputted. It has shortcomings and shortens the service life and reduces call and waiting time.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described disadvantages, and an object of the present invention is to provide a transmitting device of a mobile communication terminal to improve the efficiency of output power at a transmitting end of the mobile communication terminal.

In addition, the present invention optimizes adjacent channel noise and noise characteristics while lowering the demodulator gain at the transmitting end of the mobile communication terminal, thereby improving the transmitting end output to lower the gain of the power amplifier, thereby reducing the current consumption. Its purpose is to extend life and increase call calls and wait times as well as reduce costs.

Alternatively, an object of the present invention is to embed a small signal amplifier in a transmitting end of a CDMA terminal to improve output power efficiency and to be applicable to the field of transmitting end of a wireless communication device.

In the mobile communication terminal according to an embodiment of the present invention for achieving the above object, a transmitting apparatus includes a power amplifier for amplifying a power level of a transmission signal to transmit through an antenna; A high power detector for detecting a PDM (Pulse Division Modulation) level value by determining a power level read from the power amplifier within a voltage range; An MSM for controlling gain by applying an appropriate signal size to each level based on the PDM level value recognized by the high power detector; A demodulator for amplifying a transmission signal into a demodulation waveform according to the gain control of the MSM; A small signal amplifier for amplifying the small signal applied from the demodulator; And a BPF for filtering a signal applied from the small signal amplifier to a power amplifier by filtering only a desired frequency band.

Preferably, the small signal amplifier is connected to the rear end of the demodulator and amplifies a signal applied from the demodulator, characterized in that for outputting to the BPF.

Also preferably, the small signal amplifier amplifies the small signal -10 (dBm) applied from the demodulator to 6 (dBm) through a gain of 16 (dBm) and outputs it to the BPF to lower the gain of the power amplifier. Characterized in that. Here, the small signal amplifier is characterized in that the low noise amplifier (LNA).

Alternatively, the small signal amplifier may be installed at the rear end of the BPF to amplify the signal passing through the BPF and output the amplified signal to the power amplifier.

The present invention improves the transmission stage output by additionally providing a small signal amplifier (e.g., LNA) at the demodulator output stage in the transmission apparatus of the mobile communication terminal. It optimizes the adjacent channel noise and noise characteristics, which are general characteristics, amplifies the signal passing through the small signal amplifier and applies it to the input of the power amplifier, and then at the output level desired by the developer or operator at the output stage of the corresponding power amplifier. By increasing the transmit power in the areas commonly used in real-world situations, it reduces the gain of the corresponding power amplifier, thus reducing current consumption, which extends battery life and increases call talk and standby time. To give. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the mobile communication terminal according to an embodiment of the present invention, as shown in FIG. 1, the transmitter includes an MSM 11, a demodulator 12, a small signal amplifier 13, a BPF 14, and a power source. The amplifier 15 includes a high power detector 16, a duplexer 17, and a diplexer 18.

The MSM 11 is a core chip embedded in a mobile communication terminal, and has various functions of coding, decoding, and modem. In particular, the received signal, the local oscillation frequency, and the high power detector 16 By combining the PDM levels, the signal size suitable for each level is transmitted to the demodulator 12 through the transmission gain control signal Tx_agc_adj. That is, the MSM 11 recognizes the PDM level value from the high power detector 16 and then gains the gain of the demodulator 12 through the transmission gain control signal Tx_agc_adj based on the recognized PDM level value. Control to increase.

The demodulator 12 amplifies the transmission signal through an internal drive amplifier (not shown in the drawing for convenience of description) according to the transmission gain control signal Tx_agc_adj applied from the MSM 11, and then amplifies the corresponding signal. To the CDMA demodulation waveform. In this case, the demodulator 12 reduces the gain by 10 (dBm) and outputs the signal to the small signal amplifier 13 as a small signal of -10 (dBm).

The small signal amplifier 13 amplifies a signal applied from the demodulator 12 as, for example, an LNA, that is, a small signal -10 (dBm) applied from the demodulator 12 has a gain of 16 (dBm). Amplified to 6 (dBm) through and outputs to the BPF (14).

In addition, the small signal amplifier 13 is composed of six pins in a manner of using a transistor, pins 1 are gain control pins, pins 2 and 5 are ground pins, Pin 3 is the RF (Radio Frequency) input pin, pin 4 is the RF output pin, and pin 6 is the reference voltage pin. In this case, the corresponding reference voltage pin is shared with the input reference voltage pin of the power amplifier 15, and the gain control pin is implemented in software so as to always control with high gain.

The BPF 14 passes only a frequency band desired by a developer or an operator between the small signal amplifier 13 and the power amplifier 15, that is, the signal applied from the small signal amplifier 13 is a frequency band. Only the filter is delivered to the power amplifier 15.

The power amplifier 15 amplifies the CDMA gain, that is, amplifies the power level received through the BPF 14 with a gain of 28 (dBm) and outputs it as 31.5 (dBm) to output the duplexer 17. And through the diplexer 18 to transmit through the antenna.

The high power detector 16 determines the power level being read from the power amplifier 15 within a voltage range, and then outputs a signal (ie, PDM level value) corresponding to the appropriate voltage value to the MSM 11. )

The operation of the transmitter in the mobile communication terminal according to an embodiment of the present invention will be described with reference to the configuration diagram of FIG. 1 as follows.

First, the high power detector 16 reads the power level from the power amplifier 15 in a weak electric field situation, and then determines the read power level within a voltage range to determine a signal corresponding to an appropriate voltage value (that is, a PDM level). Value) to the MSM 11.

Accordingly, the MSM 11 combines the received signal, the local oscillation frequency, and the PDM level value of the high power detector 16 to obtain a signal size suitable for each level through the transmission gain control signal Tx_agc_adj. That is, after recognizing the PDM level value from the high power detector 16, the gain of the corresponding demodulator 12 is increased through the corresponding transmission gain control signal Tx_agc_adj based on the recognized PDM level value. To control.

At this time, in the conventional structure without the small signal amplifier 13 having a specification of -101 to -10 (dBm), the gain of the demodulator 12 is adjusted to the electrical special adjacent channel noise desired by the developer or the operator. It must be increased to 0 (dBm) with a condition that meets the specification (for example, Cell Band -80 to +8 (dBm)).

However, in the present invention, the gain of the demodulator 12 is increased only to -10 (dBm) by using the small signal amplifier 13, i.e., in the demodulator 12, the transmission gain applied from the MSM 11 is increased. After the amplified signal is amplified by the internal drive amplifier according to the control signal Tx_agc_adj, the amplified signal is converted into a CDMA demodulation waveform. At this time, the demodulator 12 cancels the gain by 10 (dBm) with a maximum contrast of -10 (dBm), and outputs the small signal -13 (dBm) to the small signal amplifier 13. Output to the signal amplifier (13).

Accordingly, the small signal -10 (dBm) input from the demodulator 12 to the small signal amplifier 13 passes through the small signal amplifier 13, that is, 6 (dBm) through the gain 16 (dBm). Is amplified and output to the BPF 14.

Then, the BPF 14 filters the signal (that is, gain 6 (dBm)) applied from the small signal amplifier 13 to the power amplifier 15 by filtering only the frequency band desired by the developer or the operator. When the 6 (dBm) output of the small signal amplifier 13 passes through the BPF 14, a loss of -2.5 (dBm) occurs, so that 3.5 (dBm) of the power amplifier 15 It is input to the input stage.

The power amplifier 15 amplifies the power level received through the BPF 14 with a gain of 28 (dBm) and outputs it as 31.5 (dBm) to output the antenna through the duplexer 17 and the diplexer 18. In this case, a loss of 4 to 5 (dBm) is generated from the output of the power amplifier 15 to the corresponding antenna input terminal, so that it is eventually transmitted to the corresponding antenna input terminal at 26.5 to 27.5 (dBm). This increases the final transmit power by 3 to 4 (dBm).

At this time, if the developer or operator desired transmission output range is set to 24 (dBm) (for example, 23 to 25 (dBm) of the is-98d specification), 2.5 to 3.5 (dBm) at the transmission output. It can be seen that the current (i.e., about 150-200 (mA)) is improved.

On the other hand, in the strong electric field situation, the most commonly used electric field and standby time electric field, the gain output of the demodulator 12 is equal to the weak electric field, 3.5 (dBm) is the power amplifier It is input to the input terminal of (15).

At this time, when satisfying the reference 0 to 10 (dBm) of the antenna power in a strong electric field situation, in the conventional structure without the small signal amplifier 13, the input of the power amplifier 15 should be 0 (dBm). The output of the power amplifier 15 should be 15 (dBm). If a loss of 4 to 5 (dBm) occurs from the output of the power amplifier 15 to the corresponding antenna input, the transmit power is 15 (dBm). Should be printed as

However, in the present invention, since the input signal of the power amplifier 15 becomes 3.5 (dBm) by using the small signal amplifier 13, the power amplifier 15 itself only needs to amplify 11.5 (dBm). Thus, it can be seen that the current is improved by 50 to 60 (mA).

On the other hand, the small signal amplifier 13 is composed of six pins in a manner using a transistor, in particular, the reference voltage pin, which is pin 6, is to be shared with the input reference voltage pin of the power amplifier 15. The gain control pin, pin 1, is always implemented in software for high gain control.

Thus, the current 10 (mA) of the demodulator 12, the current 50 ~ 60 (mA) of the power amplifier 15 (that is, the strong electric field), 150 ~ 200 (mA) 7 (mA) of the small signal amplifier Considering the loss, it can be seen that a gain of approximately 15% can be obtained in battery talk time and standby time.

For example, when the power output from the CDMA transmitter according to the prior art and the power using the small signal amplifier in the transmitter in the mobile communication terminal according to the embodiment of the present invention are regarded as the same at the input of the antenna, By reducing the gain of 2.5 to 5 (dBm) in the power amplifier under the electric field, current improvement of about 200 (mA) is achieved, and the cost savings can be achieved by lowering the battery capacity when maintaining the same talk time. Can be achieved.

Alternatively, in the mobile communication terminal according to this embodiment of the present invention, as shown in FIG. 2, the transmitting apparatus includes the MSM 21, the demodulator 22, the BPF 23, and the small signal amplifier 24. And a power amplifier 25, a high power detector 26, a duplexer 27, and a diplexer 28, each of which is connected to the input terminal of the transmission BPF 14 shown in FIG. Unlike the implementation of the signal amplifier 13, the small signal amplifier 24 is attached to the output terminal of the transmission BPF 23 to implement. At this time, 2.5 (dBm) power is increased to the input terminal of the power amplifier 25, and it is possible to input 6 (dBm) in combination with 3.5 (dBm) in FIG.

As shown in FIG. 2, when the BPF 23 is used between the rear end of the demodulator 22 and the front end of the small signal amplifier 24, the transmission output is 2.5 (dBm) or more than the configuration shown in FIG. You have a benefit.

As described above, the present invention further includes a small signal amplifier in the demodulator output stage to optimize the adjacent channel noise and noise characteristics while lowering the demodulator gain, thereby improving the transmission stage output and lowering the gain of the power amplifier to use current. This extends the life of the battery, reducing cost and increasing call and standby time.

Claims (5)

A power amplifier for amplifying the power level of the transmission signal to transmit through the antenna; A high power detector for detecting a PDM (Pulse Division Modulation) level value by determining a power level read from the power amplifier within a voltage range; A mobile station modem (MSM) for controlling gain by applying a signal size suitable for each level based on the PDM level value recognized by the high power detector; A demodulator for amplifying a transmission signal into a demodulation waveform according to the gain control of the MSM; A small signal amplifier for amplifying the small signal applied from the demodulator; And a band pass filter (BPF) for filtering a signal applied from the small signal amplifier to a power amplifier by filtering only a desired frequency band. The method of claim 1, And the small signal amplifier is connected to a rear end of the demodulator to amplify a signal applied from the demodulator and output the amplified signal to the BPF. The method of claim 1, And the small signal amplifier amplifies the small signal -10 (dBm) applied from the demodulator to 6 (dBm) through a gain of 16 (dBm) and outputs the result to the BPF. The method of claim 3, And the small signal amplifier is a low noise amplifier (LNA). The method of claim 1, And the small signal amplifier is installed at a rear end of the BPF to amplify a signal passing through the BPF and output the amplified signal to the power amplifier.

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