KR20080019761A - Front end module - Google Patents

Abstract

An FEM(Front End Module) is provided to minimize package size and improve the isolation of Rx/Tx signals by forming a single package module using a Tx part and an Rx part. An FEM(300) comprises an Rx/Tx splitting part, a PAM(Power Amplifier Module)(330), a Tx BPF(Band Pass Filter)(340), an Rx BPF(320), and an Rx/Tx processing part(350). The Rx/Tx splitting part separates and delivers RF Rx/Tx signals. The PAM(330) amplifies RF Tx signals. The Tx BPF(340) filters the RF Tx signals. The Rx BPF(320) filters RF Rx signals. The Rx/Tx processing part(350) processes baseband Rx signals and baseband Tx signals. The Rx/Tx processing part(350), which consists a Tx processing part and an Rx processing part, is implemented in a single chip component. The Tx processing part includes a Tx PLL(Phase Locked Loop), a Tx VCO(Voltage Controlled Oscillator), a Tx local oscillator, a drive amplifier, and a gain control amplifier. The Rx processing part includes an Rx PLL, an Rx VCO, an Rx local oscillator, an Rx mixer, a low noise amplifier, and an LPF(Low Pass Filter). Also the Rx/Tx processing part(350) comprises a GPS mixer and a GPS amplifier.

Description

Front end module

1 is a circuit block diagram schematically showing the components of a typical CDMA front end module.

2 is a top view illustrating a case where a general CDMA front end module is implemented on a substrate.

3 is a block diagram schematically illustrating components of a front end module according to an embodiment of the present invention;

Figure 4 is a block diagram schematically showing the components of the transmission and reception processing unit of the front end module according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: antenna 200: diplexer

300: front end module 310: duplexer

320: Rx BPF 330: PAM

340: Tx BPF 350: transmission and reception processing unit

351: LNA 352: Rx Mixer

353: synthesizer 354: LPF

355: GPS mixer 356: Rx local oscillator

357: Rx VCO 358: Rx phase locked circuit

359: AGC amplifier 360: drive amplifier

361: Tx mixer 362, 363: 1st IF amplifier, 2nd IF amplifier

364: Tx Local Oscillator 365: Tx VCO

366: Tx phase synchronization circuit 367: GPS LNA

The present invention relates to a front end module.

A front end module (FEM) is a transmitting / receiving device that controls radio signals used on a mobile communication terminal, and is a complex component in which various electronic components are serially implemented on one substrate to minimize integration space. Means.

For example, a front end module that processes a code division multiple access (CDMA) signal will be described as follows.

1 is a circuit block diagram schematically showing the components of a typical CDMA front end module.

Referring to FIG. 1, a general CDMA front end module includes a transceiver 30, a transmitter 50, a receiver 40, and a GPS (Global Position System) unit 60. ) Is implemented as a duplexer, and the transmission unit 50 includes a transmission processing module (Tx BBA or RF Transmitter) 56, a transmission filter 54 and a power amplifier module (PAM) 52. In addition, the receiver 40 includes a low noise amplifier (LNA) 42, a reception filter 44, and a reception processing module (Rx BBA or RF Receiver) 46, and the GPS unit 60. ) Is composed of a GPS filter 62 and a GPS processing module 64.

The duplexer 30 connected to the switching circuit 20 and the antenna 10 separates the transmitted / received signals and transmits them to the antenna 10 or the receiver 40. When the GPS signal and the CDMA signal are received through the antenna 10, The switching circuit 20 separates the two signals.

In addition, the reception processing module 46 and the transmission processing module 56 are connected to the baseband processing unit 70, the baseband processing unit 70 generates multimedia data by interpreting the digital signal, and based on the detected signal strength Accordingly, the power amplifier 52 is automatically gain controlled.

The transmission processing module 56 and the reception processing module 46 modulate / demodulate an intermediate frequency signal or a digital signal and process A / D or D / A conversion.

The transmission filter 54 or the reception filter 44 filters the transmission band frequency signal or the reception band frequency signal, and the power amplifier 52 and the low noise amplifier 42 each process the transmitted signal as a transmission signal or a reception signal. Amplify the signal to a predetermined size so that it can be.

The GPS unit 60 filters the GPS signal to attenuate the noise component, extracts only the corresponding band frequency, generates the intermediate frequency, and transmits the intermediate frequency to the baseband processor 70.

2 is a top view illustrating a case where a general CDMA front end module is implemented on a substrate.

According to FIG. 2, the CDMA front end module described with reference to FIG. 1 is mounted on a substrate, and the antenna 10, the switching circuit 20, and the GPS unit 60 are mounted on the substrate, and the transmission unit 50 is provided. The receiver 40 and the transceiver 30 separate each block and are mounted in the area below.

The baseband processor 70 is mounted in an area under the transmitter 50, the receiver 40, and the transceiver 30.

Since the front end module made of various electronic components simultaneously processes the transmission signal and the reception signal, the front end module is exposed to severe radio wave interference and generates the influence of signal crosstalk due to the generation of high heat, and there are many restrictions to minimize the size.

In addition, according to the structure of the general front-end module, since the receiver 40, the transmitter 50 and the transmission and reception separation unit 30 is not formed as a single module and is mounted together with other components on one substrate, it does not minimize the influence of radio waves. There is a problem in that the mounting / bonding / molding process of the device is complicated and time consuming.

In particular, since all the blocks are separated, there is a limit in minimizing the size of the CDMA front-end module, there is a problem that the material cost is increased.

The object of the present invention is, first, to provide a front end module that is minimized in size by configuring a single block (single package) of circuits composed of a single block, such as a receiver, a transmitter, a transceiver, a GPS unit.

In addition, the present invention provides a front end module in which each component of the communication system is packaged in a single package, by using a transmitter and a receiver integrated into a single chip to improve isolation and stably transmit and receive functions.

The front end module according to the present invention includes a transmission and reception separation unit for separating and transmitting the RF transmission and reception signals; A power amplifier for amplifying the RF transmission signal; A transmission band filter unit for filtering an RF transmission signal; A reception band filter unit for filtering an RF reception signal; And a transmission / reception processing unit that processes the baseband transmission signal and the baseband reception signal.

Hereinafter, a front end module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The front end module according to the embodiment of the present invention is assumed to be a communication module for processing a CDMA signal.

3 is a block diagram schematically illustrating the components of the front end module 300 according to an embodiment of the present invention.

Referring to FIG. 3, the front end module 300 according to the embodiment of the present invention includes a duplexer 310, a power amplifier module (PAM) 330, a Rx band pass filter (BPPF) 320, It includes a Tx BPF 340 and the transmission and reception processing unit 350, the duplexer 310 is connected to an external diplexer (200).

The diplexer 200 is connected to an antenna 100 and a global positioning system (GPS) BPF 500, and the transmission / reception processor 350 is located outside the GPS BPF 500 and the baseband processor 400. Connected with

The duplexer 310, the power amplification module 330, the Rx BPF 320, the Tx BPF 340, and the transmission / reception processing unit 350 are mounted on a substrate as a single chip device. Patterns such as transmission patterns, routing patterns, bonding patterns, and terminal patterns are formed, and various lumped elements and distribution elements are mounted over several layers.

The front end module 300 implemented on the substrate is implemented as a single package element through a molding process, and in particular, the transmission / reception processor 350 processes baseband transmission / reception signals as an integrated form of a conventional transmission chip and a reception chip. It includes various circuits.

Hereinafter, the front end module 300 according to the embodiment of the present invention will be described in more detail with reference to FIGS. 3 and 4.

4 is a block diagram schematically illustrating the components of the transmit / receive processing unit 350 of the front end module 300 according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the transmission / reception processor 350 includes a low noise amplifier (LNA) 351, a GPS low noise amplifier 367, an Rx mixer 352, a synthesizer 353, and a low pass filter (LPF) ( 354), GPS mixer 355, Rx Local Generator 356, Rx VCO (Voltage Controlled Oscillator) 357, Rx Phase Locked Loop (PLL) 358, Tx Phase Synchronous Circuit (366), Tx VCO (365), Tx Local Oscillator (364), First IF Amplifier (362), Second IF Amplifier (363), Tx Mixer (361), Drive Amplifier (360), and AGC (Auto Gain Control) ) Amplifier 359.

The antenna 100 receives a GPS signal and a CDMA signal and transmits the same to the diplexer 200. The diplexer 200 separates the GPS signal and the CDMA signal and transmits the GPS signal to the GPS filter 500. The CDMA signal is transmitted to the duplexer 310.

The diplexer 200 is composed of a high pass filter (HPF) and a low pass filter (LPF) composed of a high performance passive element (IPD), and the HPF is a relative signal among the signals received from the antenna. As a result, the high-band CDMA signal is passed to the duplexer 310, and the LPF filters the low-band GPS signal to the GPS filter 500.

In addition, the diplexer 200 may be provided as a single pole double throw (SPDT) switch, and the SPDT switch is a kind of integrated circuit (IC) switch, and has two positive control voltages at DC. It operates up to about 3GHz and has a very low control voltage that allows it to open and close at 2.4V.

The duplexer 310 separates the CDMA signal into a transmission signal and a reception signal and transfers the CDMA signal to the diplexer 200 or the low noise amplifier 351, respectively.

The low noise amplifier 351 amplifies a received signal by suppressing a noise component, and the Rx BPF 320 filters only mixed signals generated during the amplification process and passes only the received signal of a corresponding band.

The Rx phase synchronization circuit 358 receives a reference frequency signal from a TCXO (Temperature Compensated Crystal Oscillator; temperature compensated crystal oscillator; located outside of the front end module) 420, and receives the reference frequency signal from the phase detector, pulse / Circuits such as a voltage converter and a feedback circuit (divider) (the components of the phase synchronizer circuit) are controlled to a stable signal. Thus, the Rx VCO 357 can provide a stable and variable frequency source as needed.

The Rx local oscillator 356 generates a local oscillation signal according to the frequency source signal provided from the Rx VCO 357 and delivers it to the Rx mixer 352, and the Rx mixer 352 transmits the RF transmitted from the Rx BPF 320. The signal is mixed with the local oscillation signal to generate an intermediate frequency (IF) signal.

The synthesizer 353 separates an intermediate frequency signal in an in-phase (I) signal and a quadrature-phase (Q) signal state, and transmits the intermediate frequency signal to the LPF 354, and the LPF 354 mixes low-band noise in the mixing process. Filter out the signal.

In addition, the GPS low noise amplifier 367 low noise amplifies the GPS reception signal transmitted from an external GPS BPF 500 in a corresponding band, and the GPS mixer 355 mixes the amplified GPS signal with a local oscillation signal to generate an intermediate frequency. Convert to a band signal.

The GPS mixer 355 shares the Rx local oscillator 356 and receives a local oscillation signal.

Meanwhile, the baseband processor 400 (commonly referred to as a "base band analog" (BBA)) may include a D / A converter, a CPU, a digital modulator, a channel encoder / decoder, and the like, so that a CDMA signal or Coding / filtering the GPS signal and converting it into a digital signal.

In addition, the baseband processor 400 encodes / decodes a CDMA signal or a GPS signal, processes the signal as multimedia data, and controls an input / output device such as a display device and a keypad to provide a user interface.

The baseband processing unit 400 includes a GPS signal processing unit (Asynchronous GPS) (not shown), and the GPS signal processing unit demodulates the GPS signal and converts it into digital data.

The baseband processor 400 receives the power information detected from the power detector (not shown) to generate a control signal, and the AGC amplifier 359 amplifies the signal by adjusting the amplification gain according to the control signal. You can.

The first IF amplifier 362 and the second IF amplifier 363 amplify the intermediate frequency signals in I and Q signal states, respectively, and the amplified signal is transmitted to the Tx mixer 361.

The Tx mixer 361 converts the local oscillation signal and the intermediate frequency signal transmitted from the Tx local oscillator 364 into an RF signal, and the Tx local oscillator 364, Tx VCO 365 and a Tx phase synchronization circuit. Reference numeral 366 is similar to circuits for the Rx signal, so a detailed description thereof will be omitted.

When the RF signal is amplified, both gain amplification and power amplification have to be done. It is difficult to design one amplifier to satisfy two aspects of amplification.

Therefore, the driving amplifier 360 having a high gain value performs first order amplification at the front end, and the power amplifier module 330 secondly amplifies the power of the gain amplified signal.

As described above, the AGC amplifier 359 amplifies the transmission signal by applying a gain value differentiated according to the control signal.

The Tx BPF 340 is positioned between the AGC amplifier 359 and the power amplification module 330. The Tx BPF 340 suppresses the noise component signal and the adjacent band signal introduced during gain amplification to filter only the CDMA band transmission signal. This is transmitted to the power amplifier module 330.

The power amplifier module 330 transfers the second amplified CDMA transmission signal to the duplexer 310.

Although the present invention has been described above with reference to the embodiments, these are only examples and are not intended to limit the present invention, and those skilled in the art to which the present invention pertains may have an abnormality within the scope not departing from the essential characteristics of the present invention. It will be appreciated that various modifications and applications are not illustrated. For example, each component specifically shown in the embodiment of the present invention can be modified. And differences relating to such modifications and applications will have to be construed as being included in the scope of the invention defined in the appended claims.

According to the front-end module according to the present invention, by configuring a single package module using each component constituting the communication system, in particular the transmitter and the receiver implemented in a single chip can minimize the package size and improve the isolation of transmission and reception signals It can be effective.

In addition, according to the front-end module according to the present invention, the packaging process is simplified to reduce the production time and live cost, and the effect of radio wave interference is minimized, thereby improving the communication function.

Claims (4)

Transmission and reception separation unit for separating and transmitting the RF transmission and reception signal; A power amplifier for amplifying the RF transmission signal; A transmission band filter unit for filtering an RF transmission signal; A reception band filter unit for filtering an RF reception signal; And A front end module including a transmission and reception processing unit for processing the baseband transmission signal and the baseband reception signal. The method of claim 1, wherein the transmission and reception processing unit A transmission processor including a Tx PLL, a Tx VCO, a Tx local oscillator, a Tx mixer, a drive amplifier, and a gain control amplifier; And a transmission processor including an Rx PLL, an Rx VCO, an Rx local oscillator, an Rx mixer, a low noise amplifier, and an LPF. The method of claim 1, wherein the transmission and reception processing unit A front end module comprising a GPS mixer and a GPS amplifier. The method of claim 1, wherein the transmission and reception processing unit Front end module, characterized in that implemented in a single chip device.

Images