KR100469443B1 - Baseband selection circuit for mobile communication terminal - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a baseband selection circuit of a mobile communication terminal, and in particular, by selecting a signal transmission method between various kinds of RF and baseband, a range of RF components can be selected while accommodating multimode. The purpose is to broaden it. The present invention for this purpose, in the mobile communication terminal, the receiving RF module 200 for supporting various RF modes, the switching switch (311 ~ 318) switched to the transmission and reception signal path of each currently confirmed RF mode, and It is connected to the selector switch (311 ~ 318) with various types of signal lines, and when it is confirmed in the common mode or the differential mode, D / A and A / D processing of the transmit / receive signal of the corresponding RF mode is performed. When it is confirmed that the interface (digital interface) characterized in that it comprises an analog baseband processor 300 for parallel / serial and serial / parallel processing of the transmission and reception signal of the corresponding mode.

Description

Baseband selection circuit of mobile communication terminal {BASEBAND SELECTION CIRCUIT FOR MOBILE COMMUNICATION TERMINAL}

The present invention relates to a mobile communication terminal, and more particularly to a baseband selection circuit.

While the trend of mobile terminals in the world accommodates two or more multimodes, the size of the terminals has become smaller.

Referring to FIG. 1, a general configuration of a mobile communication terminal applying a triple mode among current multi-mode terminals is shown in FIG. 1.

In FIG. 1, '110' is an RF front-end module, '121' to '123' is a first to third mode receiving RF module, '130' is an analog baseband processor, and '140' is a digital. The baseband processor '150' is a multimedia processor.

For example, as shown in FIG. 1, a mobile communication terminal to which a triple mode is applied may be used. For example, Global System for Mobile Communications (GSM) / General Packet Radio Service (GPRS), Wideband Code Division Multiple Access (WCDMA), CDMA-2000, and TD-SCDMA (Time) There is a 3G terminal for China with Division-Synchronous Code Division Multiple Access.

However, at present, most mobile communication terminals have a limitation in that the baseband signal is fixed in shape so that only RF components capable of accommodating the corresponding signal can be selected.

For example, if the baseband uses the I / Q signal in differential mode, only components that accommodate the differential mode can be used for the RF portion, but otherwise the conversion circuit must be placed between the RF portion and the baseband. You need to add

In other words, in the current technology, multiple modem chips must be used to support multimode without a single modem chip to support various standards, and each signal is separately used in each standard. If you receive it, the PCB (Printed Circuit Board) also has a lot of lines, which complicates the circuit and PCB.

Similarly, various RF component makers and baseband signals have not been standardized at the signal interface with the RF part, which makes the assembly space and circuitry complicated to employ all signals to each RF part to accommodate a multimode terminal. . In addition, signal selection is limited, and RF component manufacturer selection is also limited.

Accordingly, the present invention enables to appropriately select a signal transmission method between various kinds of RF and baseband in order to improve the conventional problem, so as to expand the selection of RF components while accommodating multimode. An object of the present invention is to propose a baseband selection circuit of a mobile communication terminal.

That is, in the present invention, since a modem chip or an RF chip that supports some two modes is currently on the market, in order to support three or more modes, in a structure in which different RF modules and different modem chips must be used in combination, An object of the present invention is to construct a selectable buffer structure to share a shareable signal line.

1 is a block diagram of a mobile communication terminal applying a typical triple mode.

2 is a block diagram of a mobile communication terminal applying the triple mode proposed in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

200: receive RF module 300: analog baseband processor

311 to 318: changeover switch 321: digital / analog converter

322: parallel / serial converter 323: analog / digital converter

324: serial / parallel converter 400: digital baseband processor

In order to achieve the above object, the present invention provides a mobile communication terminal comprising: a receiving RF module for supporting various RF modes, a switch module switched to a transmission / reception signal path of each currently verified RF mode, and a common mode Or D / A and A / D processing of the corresponding RF mode transmission / reception signal when it is identified as differential mode, and when it is confirmed as digital interface, the transmission / reception signal of the corresponding mode is parallel / serial and serial / It is characterized by comprising a signal conversion module for parallel processing.

The switch module is switched so that the receiving RF module and the signal conversion module are connected to only the I +, Q + signal lines in the comb-on mode, and the I +, I-, Q +, Q- signal line is connected between the receiving RF module and the signal conversion module in the differential mode. In the case of the digital interface mode, it is configured to be switched between the receiving RF module and the signal conversion module using only I- (D / I) and Q- (D / Q) signal lines.

Hereinafter, the present invention will be described in detail with reference to the drawings.

In the embodiment of the present invention, the baseband selection circuit of the mobile communication terminal adopting the triple mode is described as the block diagram of FIG.

In FIG. 2, '200' is a receiving RF module and '400' is a digital baseband processor.

In FIG. 2, '300' is an analog baseband processor, '311 ~ 318' is a switching switch, '321' is a digital / analog converter, '322' is a serial / parallel converter, and '323' is an analog / digital converter. '324' is a parallel / serial conversion unit.

The changeover switches 311 ˜ 318 are single-pole double-throw (SPDT) switches.

In FIG. 2, the RF front end module connected between the receiving RF module 200 and the antenna is omitted.

The digital / analog converter 321 and the analog / digital converter 323 include a module for a common I / Q and a module for a differential I / Q.

The changeover switches 311 and 312 are connected to a comb I / Q module and a differential I / Q module, respectively, of which one terminal and the other terminal are provided in the digital / analog converter 321.

The changeover switches 313 and 314 are connected to a differential I / Q module having one terminal of which is provided in the digital / analog converter 321, and the other terminal of which is connected to the parallel / serial converter 322.

The changeover switches 315 and 316 are connected to a comb I / Q module and a differential I / Q module, respectively, of which one terminal and the other terminal are provided in the analog / digital converter 323.

The changeover switches 317 and 318 are connected to a differential I / Q module having one terminal connected to the analog / digital converter 323 and the other terminal connected to the serial / parallel converter 324.

That is, in the embodiment of the present invention, it is assumed that the reception RF module 200 supports the comb-on mode, the differential mode, and the digital interface, respectively.

First, assuming that the receiving RF module 200 supports a comb mode, the analog baseband processor 300 includes a comb I having a switching switch 311 and 312 provided in the digital / analog converter 321. / Q Switches to the I and Q signal lines of the module.

Therefore, between the receiving RF module 200 and the analog baseband processor 300, only two lines of I + and Q + are used to connect a transmission (Tx) path.

Accordingly, the digital signal input from the digital baseband processor 400 is converted into an analog signal by the digital / analog converter 321 and transferred to the receiving RF module 200 through the switch 311 and 312.

At this time, in the reception (Rx) path, only I + and Q + signals from the reception RF module 200 are transferred to the analog / digital conversion unit 323 by switching of the switching switch 315 or 316 and then digitally converted. It is delivered to the digital baseband processor 400.

In addition, assuming that the receiving RF module 200 supports a differential mode, the analog baseband processor 300 includes a differential I / I having switching switches 311 to 314 provided in the digital / analog converter 321. The I +, I-, Q +, Q- signal lines of the Q module are switched.

Therefore, between the receiving RF module 200 and the analog baseband processor 300, all four signal lines of I +, I-, Q +, and Q- are used to connect the transmission (Tx) paths.

Accordingly, the digital signal input from the digital baseband processor 400 is converted into an analog signal by the digital / analog converter 321 and transferred to the receiving RF module 200 through the switch 311 to 314.

At this time, the reception (Rx) path is switched by the switching switch (315 ~ 318) I +, I-, Q +, Q- signal from the receiving RF module 200 is transmitted to the analog / digital conversion unit 323 is digital The signal is converted and then transferred to the digital baseband processor 400.

In addition, assuming that the reception RF module 200 supports a digital interface, the analog baseband processor 300 includes a digital I (D) of the parallel / serial conversion unit 322 by the switching switches 313 and 314. / I), switch to the digital Q (D / Q) line.

Therefore, the reception RF module 200 and the analog baseband processor 300 connect the transmission (Tx) path using only two signal lines of digital I (D / I) and digital Q (D / Q) signals. .

Accordingly, the parallel signal input from the digital baseband processor 400 is converted into a serial signal by the parallel / serial converter 322 and transmitted to the receiving RF module 200 through the switching switches 313 and 314.

At this time, the reception (Rx) path is a serial / parallel conversion unit 324 only the I- (D / I), Q- (D / Q) signal in the receiving RF module 200 by switching of the switching switch (317, 318) ) Is converted into serial signal and then transferred to the digital baseband processor 400.

In other words, in the exemplary embodiment of the present invention, the switching switches 311 to 318 are disposed between the DAC / ADC stage and the receiving RF module 200 included in the analog baseband processor 300 to transmit (Tx) or receive (Rx). By allowing signal interfaces with up to four signal lines in the path, up to eight signal lines required by the prior art can be reduced by one half to allow three types of signals to be selected.

As a result, if it is possible to select a variety of signals in the manner described in the embodiment of the present invention is not only applicable to the RF components of various manufacturers, it is also possible to reduce the number of signal lines to a minimum.

Therefore, even if any manufacturer's RF component is applied to any one of various standards such as GSM / GPRS, WCDMA, CDMA2000, TD-SCDMA, and EDGE, it can be buffered so that there is no problem in applying it in a mobile communication terminal.

Meanwhile, the embodiment of the present invention can be applied to a digital IF structure that is promoted in order to apply SDR (Software-Defined Radio). Here, SDR is a technology that enables radio devices to automatically recognize radio frequencies.

As described in detail above, the present invention makes it possible to select various types of signals with a minimum input / output signal line by using a switch such as a SPDT, thereby performing a buffering function of converting various signals into signals having desired characteristics in the RF component. Therefore, there is an effect that can widen the signal selection.

In addition, the present invention can directly receive a digital signal when applied to the digital IF method has an effect that can greatly simplify the RF component.

Claims (2)

In a mobile communication terminal, Receiving RF means for supporting various RF modes, Switch means for switching to a transmission / reception signal path of each currently confirmed RF mode; First signal converting means for performing D / A and A / D processing of the transmit / receive signal of the corresponding RF mode when it is confirmed in the common mode or the differential mode; And a second signal converting means for parallel / serial and serial / parallel processing of the transmission / reception signal of the corresponding mode when it is identified as a digital interface. The method of claim 1 wherein the switch means In the come-on mode, the receiving RF means and the first signal conversion means are connected with only I + and Q + signal lines, In the differential mode, the receiving RF means and the first signal conversion means are connected by I +, I-, Q +, Q- signal lines, And in the digital interface mode, the receiving RF means and the second signal converting means connect only the I- (D / I) and Q- (D / Q) signal lines.