KR100462278B1 - Apparatus of Receive in Mobile Communication Terminal - Google Patents

Abstract

The present invention relates to a receiving apparatus of a mobile communication terminal which makes it possible to equalize an inband reception loss and to implement a transmission band signal suppression characteristic in a double manner.

In order to improve the transmission band suppression characteristic of suppressing the transmission signal conducted by the reception band filter of the duplexer in the reception device of the conventional mobile communication terminal, the insertion loss in the reception band is relatively increased, which affects the reception sensitivity. In order to have a transmission band suppression characteristic, there is a problem that the size of the duplexer must be increased.

According to the present invention, the reception band filter and the double SAW BPF of the triplexer are implemented by two filters, respectively, and the reception band signal is divided by half. Therefore, the insertion loss in the band can be reduced to the maximum. In addition, by performing the transmission band suppression in the triplexer reception band filter and the dual SAW BPF, the transmission band suppression characteristic can be obtained.

Description

Apparatus of Receive in Mobile Communication Terminal

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiving device of a mobile communication terminal, and more particularly, to a receiving device of a mobile communication terminal which enables uniform insertion loss in a reception band and dual transmission band signal suppression characteristics.

As shown in FIG. 1, a conventional CDMA mobile communication terminal receiving apparatus receives a transmission band filter 23 and one reception band filter 25 for receiving a reception band signal flowing from the antenna 10. Receives a reception band signal in a single path using a duplexer (Duplexer; DUP) 20, and inputs directly to an input of a low noise amplifier (LNA) 43 at the rear of the receiver 40 It is configured to.

In the transmission call processing, the output signal amplified by the power amplifier 35 of the transmitter 30 is transmitted from the antenna 10 to the outside through the duplexer 20. At the same time, transmission and reception of the signal are simultaneously performed. In this case, the output signal may be conducted on the reception path.

As such, the transmission band signal conducted on the reception path may be combined with numerous signals on the airwaves or various spurious distortion signals inside the terminal to act as a jammer of the reception band signal.

Accordingly, the reception band filter 25 of the duplexer 20 generally has some transmission band signal suppression (ATT) characteristics.

However, even if the transmission band signal is suppressed by the reception band filter 25 of the duplexer 20, the transmission band signal remains, but the remaining signal is applied to the LNA 43 having nonlinear characteristics, thereby causing the unwanted component to occur. There is a problem that the reception sensitivity is lowered.

In particular, when the mobile communication terminal is performing call processing at the assigned channel frequency, the duplexer 20 receives a single tone having a predetermined standard level and a frequency spaced by the standard from the assigned channel center frequency. The transmitted signal transmitted through is applied to the LNA 43 and AM modulated with a single tone, so that a portion of the third order CM product is centered on the frequency of the single tone signal, as shown in FIG. In this case, the transmission signal bandwidth is symmetrically doubled and the noise is overlapped within the allocated reception band. As a result, a decrease in reception sensitivity occurs.

As described above, in order to prevent the reception sensitivity from falling, the LNA 43 having excellent linear characteristics and the duplexer 20 having excellent transmission band suppression characteristics of the reception path filter 25 should be selected. When selecting a component as a reference, it is necessary to trade off the appropriate transmission band suppression characteristics and linear characteristics. In order to improve the transmission band suppression characteristics of the duplexer 20, the reception band filter insertion loss is relatively increased. There is a problem that the size of the duplexer 20 must be increased in order to affect the reception sensitivity and to have excellent transmission band suppression characteristics.

In particular, the PCS band duplexer has a large size by implementing a ceramic mono block technology and has a problem in that transmission band suppression characteristics vary depending on the size.

Accordingly, in order to increase reception sensitivity, the LNA 43 should have excellent third-order linear characteristics. However, when the linear characteristics are improved, power consumption increases.

In addition, since the value of FIG. 3 is obtained by considering only the transmission signal power level conducted in the duplexer 20, the actual power of a single tone desensitization cannot be obtained due to the radiation power level on the actual printed circuit board (PCB) arrangement. There is a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and uses triplexers, dual Surface Acoustic Wave (SAW) BPFs, and RF switches to equalize the in-band insertion loss and dually implement the transmission band signal suppression characteristics. An object of the present invention is to provide a receiving device of a mobile communication terminal.

1 is a diagram showing the configuration of a receiver of a conventional mobile communication terminal.

FIG. 2 is a view illustrating an in-band overlapping area when a single tone is applied in a receiving apparatus of a conventional mobile communication terminal. FIG.

3 is a diagram illustrating LNA target third-order linear characteristics according to duplexer transmission band suppression characteristics in a receiving apparatus of a conventional mobile communication terminal.

4 is a diagram showing the configuration of a receiving device of a mobile communication terminal according to the present invention;

*** Explanation of symbols for the main parts of the drawing ***

110. antenna, 120. triplexer,

123. Transmission band filter, 125, 143a. Low frequency receive band filter,

127, 143b. High frequency reception band filter, 140.

143. Dual SAW BPF, 145. RF switch,

147.SAW BPF

According to an aspect of the present invention, there is provided a reception apparatus of a mobile communication terminal, comprising: a transmission band filter unit configured to transmit a transmission signal received from a transmission unit to the antenna; A triplexer comprising a reception band filter unit for dividing and receiving a signal; A first surface acoustic wave filter unit configured of two surface acoustic wave filters to receive signals divided and output from the reception band filter unit; An RF switch unit for receiving all signals output from the surface acoustic wave filters and making them into one signal; And a single input low noise signal amplifier receiving the signal output from the RF switch and outputting the signal to the second surface acoustic wave filter.

The reception band filter unit may include: a low frequency reception band filter configured to pass a low frequency band lower than a center frequency of the reception band signal; It is characterized by comprising a high frequency reception band filter for passing a high frequency band higher than the center frequency of the reception band signal.

The first surface acoustic wave filter unit may include: a low frequency reception band filter configured to receive a signal output from the low frequency reception band filter of the reception band filter unit; And a high frequency reception band filter configured to receive a signal output by being filtered by the high frequency reception band filter of the reception band filter unit.

Further, the first surface acoustic wave filter unit may be connected to an output terminal of the reception band filter unit of the triplexer to implement a transmission band suppression characteristic.

The RF switch may be implemented as a single-pole double-throw (SPDT) RF switch.

Hereinafter, a reception apparatus of a mobile communication terminal according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

4 illustrates a road, a triplexer 120, a double SAW BPF 143, an RF switch 145, an LNA 147, and a configuration of a receiver of a mobile communication terminal according to the present invention; A SAW BPF 149 is provided.

In such a configuration, the triplexer 120 transmits a transmission signal received from the transmitter 130 to the antenna 110 using the entire band as a pass band, and the antenna 110 at the antenna 110. Two reception band filters for receiving an incoming reception band signal in a dual path, that is, a low frequency reception band filter 125 for passing a low frequency band lower than the center frequency, and a high frequency reception band filter for allowing a high frequency band higher than the center frequency ( 127).

As described above, when the reception band signal is divided into the low frequency band and the high frequency band based on the center frequency, the in-band insertion loss can be reduced.

That is, in the present invention, the reception band filters 125 and 127 of the triplexer 120 are designed not to improve the transmission band suppression characteristics but to design the insertion loss in the band as much as possible.

On the other hand, the dual SAW band pass filter (BPPF) 143 is connected to the output terminal of the triplexer 120, and receives the signal filtered out by each of the reception band filters 125 and 127 of the triplexer 120, respectively. Two SAW BPFs, that is, a low frequency reception band filter 143a for receiving a signal output from the low frequency reception band filter 125 of the triplexer 120, and a high frequency reception band filter 127 of the triplexer 120. A high frequency reception band filter 143b for receiving a signal filtered and output from

As described above, like the triplexer 120, the dual SAW BPF 143 also includes two filters to receive the reception band signal divided into a low frequency band and a high frequency band, thereby reducing in-band insertion loss.

In other words, the dual SAW BPF 143, like the reception band filters 125 and 127 of the triplexer 120, does not aim to improve the transmission band suppression characteristics but to reduce the insertion loss in the band. Design.

However, since the transmission band suppression is performed by the reception band filters 125 and 127 of the triplexer 120 and the dual SAW BPF 143, for example, the reception band filter 125 of the triplexer 120 is doubled. Assuming that the transmission band suppression characteristic of the 127 is about 40 dB and the transmission band suppression characteristic of the double SAW BPF 143 is about 20 dB, the reception band filters 125 and 127 of the triplexer 120 The dual SAW BPF 143 enables a high transmission band suppression characteristic of about 60 Hz or more.

Accordingly, high transmission band suppression characteristics can be obtained without increasing transmission band suppression characteristics of the reception band filters 125 and 127 of the triplexer 120 and the dual SAW BPFs 143.

On the other hand, the RF switch 145 is connected to the output terminal of the dual SAW BPF 143, receives all the reception band signal is filtered by each filter (143a, 143b) of the dual SAWBPF 143 is separated into a dual path and output By making a single path, both the signal filtered and output by the low frequency reception band filter 143a of the double SAW BPF 143 and the signal filtered and output by the high frequency reception band filter 143b are received.

As described above, the RF switch 145 may be implemented as a single-pole double-throw (SPDT) RF switch.

The LNA 147 is connected to the output terminal of the RF switch 145, receives the received signal output from the RF switch 145, and delivers the received signal to the SAW BPF 149.

As described above, in the triplexer 120 and the dual SAW BPF 143, the reception band signal is divided into a low frequency band and a high frequency band and received. The low frequency band and the high frequency band vary in bandwidth depending on the system. Although generally shown in Table 1, it is designed to occupy half of the total bandwidth.

Cellular systems US-PCS System Low frequency band Carrier Frequency≤881.52MHz Channel number High frequency band Carrier Frequency> 881.52MHz Channel number> 600

Hereinafter, an operation of a reception device of a mobile communication terminal according to the present invention will be described with reference to FIG. 3.

First, the reception band signal introduced through the antenna 110 is applied to the triplexer 120. Among the reception band signals applied to the triplexer 120, the low frequency band signal is filtered by the low frequency reception band filter 125. The high frequency band signal is filtered by the high frequency reception band filter 127 and output.

As described above, in the reception band filters 125 and 127 of the triplexer 120, the reception band signal is divided into a low band signal and a high band band signal, and then filtered and output, thereby reducing in-band insertion loss.

Thereafter, the signal output from the low frequency reception band filter 125 of the triplexer 120 is applied to the low frequency reception band filter 143a of the double SAW BPF 143, filtered, and then output. The signal output from the high frequency reception band filter 127 is applied to the low frequency reception band filter 143b of the double SAW BPF 143 and filtered, and then is output. The reception band filters 125 and 127 of the triplexer 120 are output. Similarly, in the dual SAW BPF 143, the reception band signal is divided into a low frequency band signal and a high frequency band signal, and then filtered and outputted, thereby reducing in-band insertion loss.

In addition, by suppressing a signal in which the reception band filters 125 and 127 of the triplexer 120 have already suppressed the transmission band once more in the double SAW BPF 143, high transmission band suppression characteristics can be obtained.

As described above, the signal output from the low frequency reception band filter 143a of the dual SAW BPF 143 and the signal output from the high frequency reception band filter 143b of the dual SAW BPF 143 are connected to the dual SAW BPF 143. It is applied to the RF switch 145 connected to the output terminal and merged into one signal, and the combined signal from the RF switch 145 is applied to the LNA 147 of a single input connected to the output terminal of the RF switch 145. .

The receiving device of the mobile communication terminal of the present invention is not limited to the above-described embodiment, and can be implemented in various modifications within the range allowed by the technical idea of the present invention.

According to the receiving apparatus of the mobile communication terminal of the present invention as described above, the reception band filter of the triplexer and the dual SAW BPF are implemented by two filters, respectively, and the reception band signal is divided in half to receive the maximum in-band insertion loss. There is an effect that can be reduced. In addition, by performing the transmission band suppression in the triplexer reception band filter and the dual SAW BPF, the transmission band suppression characteristic can be obtained. In addition, as the transmission band suppression characteristic can be implemented to be high, it is not necessary to improve the LNA's third-order linear characteristics, thereby making it easy to select components and solving the problem of increased power consumption. In addition, as the transmission band suppression characteristic can be implemented high, sufficient specification margin is generated, so that the radiation power level generated on the PCB layout during development design does not have to be concerned.

Claims (5)

A reception device of a mobile communication terminal configured to receive a signal output from a reception band filter unit of a duplexer receiving a reception band signal from an antenna and output the signal output from a low noise signal amplifier to a surface acoustic wave filter. A triplex filter comprising a transmission band filter unit configured to transmit a transmission signal received from the transmitter to the antenna, and a reception band filter unit configured to receive and receive a reception band signal introduced from the antenna by two filters; A first surface acoustic wave filter unit configured of two surface acoustic wave filters to receive signals divided and output from the reception band filter unit; An RF switch unit for receiving all signals output from the surface acoustic wave filters and making them into one signal; And a single input low noise signal amplifier for receiving a signal output from the RF switch and outputting the signal to a second surface acoustic wave filter unit. The method of claim 1, wherein the reception band filter unit, A low frequency reception band filter for passing a low frequency band lower than a center frequency of the reception band signal; And a high frequency reception band filter for passing a high frequency band higher than a center frequency of the reception band signal. The method of claim 1, wherein the first surface acoustic wave filter, A low frequency reception band filter for receiving a signal filtered by the low frequency reception band filter of the reception band filter unit; And a high frequency reception band filter configured to receive a signal output by being filtered by the high frequency reception band filter of the reception band filter unit. delete The method of claim 1, wherein the RF switch, Receiving apparatus of a mobile communication terminal, characterized in that implemented as a single-pole double-throw (SPDT) RF switch.