KR20020054523A - Dual band transceiver of mobile communication terminal - Google Patents

Abstract

PURPOSE: A dual band transceiver of mobile communication terminal is provided to combine an IF frequency of 85.38 MHz band using in the reception side of DCS type with an IF frequency of 220.38MHz band using in the reception side of PCS type, thereby simplifying the circuit construction of IF peripheral. CONSTITUTION: A diplexer(11) combines a DCS duplexer(12) with a PCS duplexer(13) for operating a mobile terminal according to DCS type or PCS type. The first and second LNA(Low Noise Amplifier)s(14,15) amplify each RF frequency received from the duplexers(12,13). The first and second RF SAW filters(16,17) remove the noise of each RF frequency signal amplified from the LNAs(14,15). A first switch(18) switches each RF signal passing through the SAW filters(16,17). An MSM(Mobile Station Modem)(19) controls the whole operation of the mobile terminal and outputs a control signal for generating a local frequency. A second switch(20) switches the control signal output from the MSM(19). DCS PLL(21) and PSC PLL(22) output a voltage control signal for generating a local frequency through the control signal by the second switch(20). A first VCO(23) generates DCS local frequency of 954-979MHz band. A second VCO(24) generates a PCS local frequency of 1620-1650MHz band. A first splitter(26) divides DCS local frequency of 954-979MHz band.

Description

DUAL BAND TRANSCEIVER OF MOBILE COMMUNICATION TERMINAL}

The present invention relates to a dual band transceiver of a mobile communication terminal. Particularly, in a mobile communication terminal performing a mixed service of a DCS (Digital Cellular System) and a PCS (Personal Communication Service), a DCS reception is performed. Dual band of mobile communication terminal that simplifies circuit configuration around IF and greatly reduces multi-path RF signal line by integrating IF frequency used by PC side to IF frequency used by PCS receiver. It is about a transceiver.

In general, a mobile communication system provides a mobile communication service using a DCS scheme or a PCS scheme. In the DCS scheme, a frequency of 824 to 894 MHz is used, and the PCS scheme uses a frequency of 1750 to 1870 MHz.

Conventionally, a mobile communication terminal capable of providing a mobile communication service by using a DCS method and a PCS method having different usage frequencies is designed as described above. In particular, when designing a dual band mobile communication terminal, a DCS method and a PCS method are used frequencies. Because of this difference, different RF paths must be designed.

That is, FIG. 1 is a simplified configuration diagram of a dual band transceiver of a conventional mobile communication terminal. In the DCS method, in the case of a receiving side (RX), a DCS PLL 1 and a VCO 2 are connected to a mixer through a mixer 4. The IF frequency of 85.38 MHz is output by mixing the local frequency in the 954-979 MHz band generated by the RF signal and the 869-894 MHz RF, and in the case of the transmitting side TX, the splitter 5 through the mixer 5. The RF frequency in the 824-849 MHz band is output by mixing the local frequency in the 954-979 MHz band and the IF frequency in the 130.38 MHz band separated by (3).

In the PCS method, in the case of the receiving side RX, the mixer 9 mixes the local frequency of the 1620-1650 MHz band and the RF frequency of 1840-1870 MHz generated by the PCS PLL 6 and the VCO 7 through the mixer 9. Outputs an IF frequency of 220.38 MHz, and in the case of the transmitting side TX, the local frequency of the 1620 to 1650 MHz band separated by the splitter 8 through the mixer 10 and the IF frequency of 130.38 MHz band are mixed to 1750. Outputs an RF frequency in the ˜1780 MHz band.

The dual band transceiver of the conventional mobile communication terminal configured as described above uses the same IF frequency in the 130.38 MHz band on the transmitting side implemented by the DCS scheme and the PCS scheme.

On the other hand, the receiving side implemented by the DCS scheme and the PCS scheme uses different IF frequencies.

That is, an IF frequency of 85.38 MHz band is used at the receiver side implemented by the DCS scheme, and accordingly, an IF filter capable of passing the IF frequency of the 85.38 MHz band must be used separately, and a 220.38 MHz band is also used at the receiver side of the PCS scheme. Because the IF frequency is used, an IF filter that can pass this IF frequency in the 220.38MHz band must be used separately.

However, as described above, the dual band transceiver of the conventional mobile communication terminal is composed of dual RF paths, which complicates the circuit configuration around the IF, and the use of more RF signal lines makes it difficult to construct an appropriate signal line. There is a problem in that the RF performance of the overall mobile communication terminal is lowered.

The present invention is to solve the above problems, the purpose of the mobile communication terminal performing a mixed service of the DCS and PCS scheme, the IFS of the 85.38MHz band used by the DCS scheme receiving side of the PCS scheme It is to provide a dual band transceiver of a mobile communication terminal that simplifies the circuit configuration around the IF and greatly reduces the multi-path RF signal line by integrating into the IF frequency in the 220.38MHz band used at the receiving side.

1 is a simplified configuration diagram of a dual band transceiver of a conventional mobile communication terminal,

2 is a block diagram of a dual band transceiver of a mobile communication terminal according to the present invention;

3 is a block diagram showing another embodiment of the local frequency generator of FIG.

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

11: diplexer 12: DCS duplexer

13: PCS duplexer 14,15: 1st, 2nd LNA

16, 17, 37, 38: first to fourth RF SAW filter

18, 20, 29, 35, 36: first to fifth switches

21: DCS PLL22: PCS PLL

23,34: 1st, 2nd VCO 25, 26: 1st, 2nd splitter

27: oscillator 28,30,37: first to third mixer

31,34: 1st, 2nd IF SAW filter 32: IFR

33: IFT 39,40: 1st, 2nd PA

The dual band transceiver of the mobile communication terminal of the present invention for achieving the above object, the DCS local to generate the transmission and reception side IF frequency and RF frequency according to the control signal of the MSM in the mobile communication terminal implemented by the DCS and PCS scheme A local frequency generator for generating a second specific local frequency by the DCS scheme for integrating the frequency, the PCS local frequency, and the receiver-side IF frequency in the DCS scheme into the receiver-side IF frequency in the PCS scheme, and an IFT in the mobile communication terminal. RF frequency generation and output processing unit by the DCS method of generating and output-processing the RF frequency of the transmitting side by mixing the transmission side IF frequency by the DCS method and the DCS local frequency generated by the local frequency generator Receiving side RF frequency and local frequency generation by DCS method passing through diplexer and DCS duplexer in communication terminal IF frequency generation and reception processing unit according to DCS method for generating and receiving receiving IF frequency by mixing second specific local frequency generated by DCS method and PCS method transmitted from IFT in mobile communication terminal. RF frequency generation and output processing unit by the PCS method of generating and outputting the transmitting RF frequency by mixing the transmitting IF frequency and the PCS local frequency generated by the local frequency generating unit, a diplexer and a PCS in the mobile communication terminal. Consists of IF frequency generation and reception processing unit by PCS method of generating and receiving processing IF frequency by mixing reception side RF frequency through PCS method and PCS local frequency generated by the local frequency generator. It is characterized by.

Hereinafter, a configuration and operation of a dual band transceiver of a mobile communication terminal according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram of a dual band transceiver of a mobile communication terminal according to the present invention, and a diplexer combining a DCS duplexer and a PCS duplexer so that the mobile communication terminal operates according to a DCS scheme or a PCS scheme, respectively. 11, a DCS duplexer 12 that is responsible for transmitting and receiving signals according to the DCS scheme, a PCS duplexer 13 that is responsible for transmitting and receiving signals according to the PCS scheme, the DCS duplexer 12, and a PCS duplexer ( 13 and the first and second low noise amplifier (LNA) 14, 15 for low noise amplification of the signal of each RF frequency received at 13), and the amplified angles at the first and second LNA 14, 15, respectively. First and second RF SAW filters 16 and 17 for removing noise of the RF frequency signal, and switching each RF frequency signal passed through the first and second RF SAW filters 16 and 17; 1 switch 18 and a control signal for controlling the overall operation of the mobile communication terminal and generating a local frequency MSM (Mobile Station Modem) (19) for outputting, the second switch 20 for switching the control signal output from the MSM (19), which is input according to the switched path in the second switch (20) DCS PLL 21 and PCS PLL 22 for outputting a voltage control signal for generating a local frequency through a control signal, and DCS Local in the 954-979 MHz band according to the voltage control signal output from the DCS PLL 21. A first VCO 23 for generating a frequency, a second VCO 24 for generating a PCS local frequency in a band of 1620 to 1650 MHz according to the voltage control signal output from the PCS PLL 22, and the first VCO ( A first splitter 25 for separating the DCS local frequency in the 954 to 979 MHz band generated in 23) and a second splitter 26 for separating the PCS local frequency in the 1620 to 1650 MHz band generated in the second VCO 24. ), An oscillator 27 generating a first specific local frequency of 135 MHz, and 9 separated from the first splitter 25 1089 to 1012 for integrating the receiving side IF frequency in the DCS scheme into the receiving side IF frequency in the PCS scheme by mixing the DCS local frequency in the 54 to 979 MHz band and the first specific local frequency of 135 MHz generated by the oscillator 27. A first mixer 28 generating a second specific local frequency in the 1114 MHz band, and a second specific local frequency in the 1089 to 1114 MHz band generated by the first mixer 28 and the second splitter 26. A third switch 29 for switching the PCS local frequency in the 1620 to 1650 MHz band, an RF frequency according to the DCS method or the PCS method passing through the first switch 18, and a local passing through the third switch 29; A second mixer 30 for mixing a frequency and outputting a receiving side IF frequency in a 220.38 MHz band, a first IF SAW filter 31 for removing noise of an IF frequency signal output from the second mixer 30, and IF frequency passing through the first IF SAW filter 31 IFR (Intermediate Frequency Receiver) 32 for receiving and processing signals, IFT (Intermediate Frequency Transmitter) 33 for transmitting and processing IF frequency signals, and noise of IF frequency signals transmitted and processed by the IFT 33 are removed. Switching between a second IF SAW filter 34 and a DCS local frequency of 954 to 979 MHz band separated by the first splitter 25 and a PCS local frequency of 1620 to 1650 MHz band separated from the second splitter 26. The fourth switch 35 and the local frequency passing through the fourth switch 35 and the transmitting IF frequency in the 130.38 MHz band passing through the second IF SAW filter 34 are mixed to obtain 824 by DCS. A third mixer 37 for generating a transmitting side RF frequency in the ˜849 MHz band or a transmitting side RF frequency in the 1750 to 1780 MHz band by the PCS scheme, and for switching each RF frequency signal output from the third mixer 37. Passing through the fifth switch 36 and the fifth switch 36 Power amplification of each RF frequency signal passed through the third and fourth RF SAW filters 37 and 38 to remove noise of each RF frequency signal, and the third and fourth RF SAW filters 37 and 38. The first and second power amplifiers (PAs) 39 and 40 output to the DCS duplexer 12 and the PCS duplexer 13.

At this time, the configuration of the DCS PLL 21, the first VCO 23, the first splitter 25, the oscillator 27, the first mixer 28 generates a second specific local frequency in the 1089 ~ 1114MHz band As the local frequency generator 50, the second mixer generates a second specific local frequency in the 1089 to 1114 MHz band so that the receiving side of the DCS method generates an IF frequency in the 220.38 MHz band that is the IF frequency of the PCS method. Output to (30).

FIG. 3 is a block diagram illustrating another embodiment of the local frequency generator 50, and generating different local frequencies through control signals input according to a path switched by the second switch 20. Referring to FIG. First and second DCS PLLs 41 and 42 for outputting a voltage control signal, and an 85.38 MHz band used by the receiving side of the DCS scheme according to the voltage control signal output from the first DCS PLL 41. A first VCO 43 for generating a second specific local frequency in the 1089 to 1114 MHz band for integrating the IF frequency into the IF frequency in the 220.38 MHz band used by the receiving side of the PCS scheme; and the second DCS PLL 42. A second VCO 44 generates a DCS local frequency in the 954 to 979 MHz band with the fourth switch 35 according to the voltage control signal outputted from.

Referring to the operation of the dual-band transceiver of the mobile communication terminal of the present invention configured as described above are as follows.

When the mobile communication terminal is operated by the DCS scheme, during transmission, an IF frequency signal of 130.38 MHz band transmitted by the IFT 33 is passed through the second IF SAW filter 34 to remove noise and then the first Output to the mixer 3 (37).

In addition, the second switch 20 is switched to the DCS PLL 21 in the local frequency generator 50 to output a control signal output from the MSM 19 to the DCS PLL 21.

Subsequently, according to the voltage control signal generated by the DCS PLL 21, a first VCO 23 generates a DCS local frequency of 954 to 979 MHz, and is separated by the first splitter 25 to separate the fourth switch ( 35) outputs the DCS local frequency of the 954 ~ 979MHz band to the third mixer (37).

Accordingly, the third mixer 37 mixes the input DCS local frequency of the 954 to 979 MHz band and the transmitting IF frequency of the 130.38 MHz band to generate a transmitting side RF frequency signal of the 824 to 849 MHz band by the DCS scheme. Next, the third RF SAW filter 37 is output to the third RF SAW filter 37 through the fifth switch 36.

Thereafter, the RF frequency signal passing through the third RF SAW filter 37 is amplified by the first PA 39 and then output through the DCS duplexer 12 and the diplexer 11.

In case of reception, the first LNA 14 and the first RF SAW filter 16 receive the RF signal of the receiving side of the 869 to 894 MHz band by the DCS method inputted through the diplexer 11 and the DCS duplexer 12. After amplifying low noise and removing noise, the output is output to the second mixer 30 through the first switch 18.

In addition, the second switch 20 is switched to the DCS PLL 21 in the local frequency generator 50 to output a control signal output from the MSM 19 to the DCS PLL 21.

Subsequently, according to the voltage control signal generated by the DCS PLL 21, the first VCO 23 generates a DCS local frequency of 954 to 979 MHz, and is separated through the first splitter 25 to separate the oscillator 27. Output from the first mixer 28, the first specific local frequency in the 135 MHz band.

That is, the second specific local frequency of the 1089 to 1114MHz band is generated through the first mixer 28 so that the receiving side of the DCS method generates the IF frequency of the 220.38MHz band, which is the IF frequency of the PCS method.

Thereafter, the second mixer 30 is an RF frequency signal of the 869 to 894 MHz band by the DCS method input through the first switch 18 and the first mixer input through the third switch 29 ( A second specific local frequency in the 1089 to 1114 MHz band of 28) is mixed to generate a receiving side IF frequency signal in the 220.38 MHz band by the DCS scheme.

Then, the IF frequency signal of the 220.38MHz band is passed through the first IF SAW filter 31 to remove noise and then received by the IFR 32.

Next, when the mobile communication terminal is operated by the PCS method, the IF frequency signal of 130.38 MHz band by the PCS method transmitted by the IFT 33 passes through the second IF SAW filter 34. After removing the noise, the noise is output to the third mixer 37.

In addition, the second switch 20 is switched to the PCS PLL 22 in the local frequency generator 50 to output a control signal output from the MSM 19 to the PCS PLL 22.

Subsequently, according to the voltage control signal generated by the PCS PLL 22, the second VCO 24 generates a PCS local frequency in a band of 1620 to 1650 MHz, and is separated through the second splitter 26 to separate the fourth switch ( 35) outputs the PCS local frequency in the 1620 to 1650MHz band to the third mixer 37.

Accordingly, the third mixer 37 mixes the PCS local frequency of the input 1620-1650 MHz band and the IF frequency of the 130.38 MHz band by the PCS method to transmit the RF side signal of the 1750-1780 MHz band by the PCS method. And output to the fourth RF SAW filter 38 through the fifth switch 36.

Thereafter, the RF frequency signal passing through the fourth RF SAW filter 38 is amplified by the second PA 40 and then output through the PCS duplexer 13 and the diplexer 11.

In the case of reception, the RF frequency signal of the 1840-1870 MHz band by the PCS scheme inputted through the diplexer 11 and the PCS duplexer 13 is used to convert the second LNA 15 and the second RF SAW filter 17. After low noise amplification and noise removal, the output is output to the second mixer 30 through the first switch 18.

In addition, the second switch 20 is switched to the PCS PLL 22 in the local frequency generator 50 to output a control signal output from the MSM 19 to the PCS PLL 22.

Subsequently, according to the voltage control signal generated by the PCS PLL 22, the second VCO 24 generates a PCS local frequency in the band 1620 to 1650 MHz, and is separated through the second splitter 26 to separate the third switch ( 29) outputs the PCS local frequency of the 1620 ~ 1650MHz band to the second mixer (30).

Accordingly, the second mixer 30 receives the RF side signal of the 1840-1870 MHz band by the PCS method input through the first switch 18 and the third input through the third switch 29. The PCS local frequencies of the 1620-16504 MHz band separated by the two splitters 26 are mixed to generate an IF frequency signal of the 220.38 MHz band by the PCS method.

Then, the IF frequency signal of the 220.38MHz band is passed through the IF SAW filter 31 to remove noise and then received by the IFR 32.

On the other hand, the 1089 to 1114MHz band for generating the IF frequency of 220.38MHz band by the PCS scheme also through the first DCS PLL 41 and the first VCO 43 in the local frequency generator 50 shown in FIG. Generate a second specific local frequency of the output via the third switch 29 to the second mixer (30).

That is, the data register of the first DCS PLL 41 is modified so that the data about the local frequency included in the control signal output from the MSM 19 can be recognized as the 1089 to 1114 MHz band instead of the 954 to 979 MHz band. .

As described above, the present invention integrates the IF frequency of the 85.38MHz band of the DCS scheme into the IF frequency of the 220.38MHz band of the PCS scheme at the receiving end of the mobile communication terminal, thereby combining the mixer and the IF part in common, that is, single. By configuring a single path, the circuit configuration around the IF can be simplified and the cost of components can be reduced.

In addition, since the RF signal line of the multipath can be greatly reduced in the limited board, the interference between signals is reduced, thereby improving the overall RF performance of the mobile communication terminal.

Claims (5)

Receiving DCS local frequency, PCS local frequency, and receiving side IF frequency in DCS scheme in PCS scheme in order to generate the transmit / receive IF frequency and RF frequency according to the control signal of MSM in mobile communication terminal implemented by DCS and PCS scheme. A local frequency generator for generating a second specific local frequency by a DCS scheme for integrating to the side IF frequency; Generation of RF frequency by DCS method of generating and outputting RF side of RF by mixing the transmitting IF frequency by DCS method and the DCS local frequency generated by the local frequency generator. An output processor, A receiver side RF frequency is generated and received by mixing a RF side of a receiver having a DCS scheme passed through a diplexer and a DCS duplexer in a mobile communication terminal with a second specific local frequency of the DCS scheme generated by the local frequency generator. IF frequency generation and reception processing unit by the DCS method to process, Generation of RF frequency by PCS method of generating and outputting RF side of RF by mixing transmitter side IF frequency by PCS scheme transmitted by IFT in mobile communication terminal and PCS local frequency generated by local frequency generator. An output processor, By a PCS method that generates and receives a receiving side IF frequency by mixing the receiving side RF frequency and the PCS local frequency generated by the local frequency generator by passing through the diplexer and the PCS duplexer in the mobile communication terminal. Dual band transceiver of the mobile communication terminal, characterized in that the IF frequency generating and receiving processing unit. The method of claim 1, wherein the local frequency generator, A DCS PLL and a PCS PLL for outputting a voltage control signal for generating different local frequencies according to the control signal output from the MSM; A first VCO generating a DCS local frequency according to the voltage control signal output from the DCS PLL; A second VCO generating a PCS local frequency according to the voltage control signal output from the PCS PLL; A first splitter separating the DCS local frequency generated in the first VCO; A second splitter separating the PCS local frequency generated in the second VCO; An oscillator generating a first specific local frequency, Dual band of the mobile communication terminal comprising a mixer for generating a second specific local frequency by the DCS method by mixing the DCS local frequency separated from the first splitter and the first specific local frequency generated by the oscillator Transceiver. 3. The dual band transceiver of a mobile communication terminal according to claim 2, wherein the first specific local frequency is 135 MHz. According to claim 1 or claim 2, Local frequency generator for generating a second specific local frequency and DCS local frequency by the DCS scheme, First and second DCS PLLs for outputting a voltage control signal for generating different local frequencies according to the control signal output from the MSM; A first VCO generating a second specific local frequency according to a DCS scheme according to the voltage control signal output from the first DCS PLL; And a second VCO generating a DCS local frequency according to the voltage control signal output from the second DCS PLL. The dual band transceiver of a mobile communication terminal according to claim 1 or 2, wherein the second specific local frequency according to the DCS scheme is 1089 to 1114 MHz.