KR100650852B1 - Multi mode mobile phone - Google Patents

Abstract

A multi-mode mobile communication terminal is provided to use a roaming service and view SDMB(Satellite Digital Multimedia Broadcasting) although a user does not buy an additional terminal in a trip abroad by mounting a dual band antenna and an SDMB dedicated gap filler antenna in an existing mobile communication terminal. A diplexer(106) separates a communication frequency signal and a broadcasting frequency signal from a signal received from the first antenna(136). An SPDT(Single Pole Double Throw) switch(109) provides a signal from the diplexer(106) to one of a CDMA(Code Division Multiple Access) communication unit(112) and a GSM(Global System for Mobile communication) unit(115). The CDMA communication unit(112) processes a CDMA signal. The GSM unit(115) processes a GSM signal. The first LNA(Low Noise Amplifier)(127) minimizes and amplifies a noise of the broadcasting frequency signal separated from the diplexer(106). The second LNA(127) minimizes and amplifies a signal noise received from the second antenna(139). An SDMB RF(Radio Frequency) unit(124) demodulates signals received from the first LNA(127) and the second LNA(130). An SDMB baseband processing unit(121) processes a baseband signal passing through the SDMB RF unit(124).

Description

Multi mode mobile terminal {multi mode mobile phone}

1 is an internal configuration diagram of a mobile communication terminal of the present invention.

<Explanation of symbols on main parts of the drawings>

Antenna 1-136 CDMA Communication Unit-112

Antenna 2-139 GSM Communication Unit-115

Matching circuit-103, 133 SDMB RF section-124

Diplexer-106 SDMA Baseband Processor-121

LNA-127, 130 Controls-118

SPDT Switch-109 Mobile Terminal-100

The present invention relates to a multi-mode mobile communication terminal, and more particularly, to a multi-mode mobile communication terminal that supports a CDMA mode and a GSM mode in one terminal, and simultaneously supports satellite DMB.

The mobile communication system used in Europe is a global system for mobile communication (GSM), which is a type of time division multiple access (TDMA), which uses a 900 MHz radio frequency band and a 1.8 GHz radio frequency band. .

In addition, there is a universal mobile telecommunication system (UTMS), which is a wideband code division multiple access (WCDMA) or code division multiple access (CDMA) method, which is the same concept as IMT-2000, the next generation mobile communication system in Korea. Transfer data at high speed of 2Mbps using. Accommodating the above GSM and UTMS schemes into one mobile communication terminal is referred to as dual mode.

Recently, interest in digital broadcasting using a mobile communication terminal, in particular, digital multimedia broadcasting (DMB) service has increased. DMB refers to digital multimedia broadcasting service. Digitally modulates various multimedia signals such as voice and video through portable receivers such as mobile phones and PDAs, and enjoys CD-level audio and DVD-class video on the go, and is a next-generation broadcasting service that satisfies both mobility and quality. It is attracting attention as.

   DMB service is attracting attention in terms of convergence of broadcasting and communication in addition to the next generation broadcasting service. Currently, the DMB market is divided into satellite DMB, which is led by telecommunication companies, and terrestrial DMB, which is led by terrestrial broadcasters such as KBS and MBC. The biggest difference between satellite DMB and terrestrial DMB is where the radio waves are sent from. In the case of satellite DMB, the program provider sends the content to the satellite DMB broadcasting center, which sends it to the satellite and sends it back to the portable terminal or vehicle receiver. In some places where there is no radio wave, a repeater called a gap filler is used. Terrestrial DMB is a method in which radio waves are transmitted to a terminal through a terrestrial transmission station.

In the related art, there was no terminal supporting the dual mode terminal and the satellite DMB function at the same time, and therefore, there was a problem in that the purchase cost of the terminal was consumed by renting a separate terminal during overseas business trips and travels, and the user was inconvenient to carry. . In addition, there was a problem that users cannot use the functions of various mobile communication terminals because there was no terminal providing a broadcasting function anytime and anywhere when traveling abroad.

The present invention has been made in view of this point, and the conventional mobile communication terminal is equipped with a dual band antenna and an SDMB-only gap filler antenna, so that a roaming service can be used without having to purchase a separate terminal when traveling abroad or traveling. In addition, the present invention provides a multi-mode mobile communication terminal that enables users to conveniently use satellite DMB broadcasting.

According to an aspect of the present invention, there is provided a multi-mode mobile communication terminal operating in a GSM mode and a CDMA mode, wherein a frequency signal and a broadcast frequency for broadcasting are transmitted from a signal received from a first antenna, a second antenna, and the first antenna. A diplexer for separating a frequency signal, an SPDT switch for switching a signal from the diplexer to be connected to one of a CDMA communication unit and a GSM communication unit, a CDMA processing unit for processing a CDMA signal, and a GSM signal A GSM communication unit for processing, a first LNA that minimizes and amplifies noise of a broadcast frequency signal separated from the diplexer, a second LNA that minimizes and amplifies signal noise received from the second antenna, and the first LNA And an SDMB RF unit for demodulating a signal received from the second LNA, and an S band processing baseband signal passing through the SDMB RF unit. A DMB baseband processor and a CDMA baseband signal or a GSM baseband signal are processed, and in the CDMA mode, the SPDT switch is controlled to be connected from the diplexer to the CDMA communication unit, and in the GSM mode, the diplexer is connected to the GSM mode. And a control unit for controlling the SPDT switch.

In this case, the first antenna is a dual band antenna covering 800 MHz and 2.6 GHz bands simultaneously, and the second antenna is a gap filler antenna dedicated to SDMB. In addition, the communication frequency is a frequency of 800MHz band for GSM, the broadcast frequency is a frequency of 2.6GHz band for SDMB. The SDMB RF unit selects a signal having a good level from a signal input to the diplexer via the first antenna and a signal input to the diplexer via the second antenna to improve reception sensitivity with a diversity function.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an internal configuration diagram of a multi-mode mobile communication terminal of the present invention.

The mobile communication terminal 100 of the present invention includes a first antenna 136, a second antenna 139, a diplexer 106, an LNA 127, 130, an SPDT switch 109, and an SDMB RF unit 124. And an SDMB baseband processor 121, a CDMA communication unit 112, a GSM communication unit 115, and a control unit 118.

The first antenna 136 is a dual band antenna that simultaneously covers the 800 MHz and 2.6 GHz bands.

The second antenna 139 is a gap filler antenna dedicated to Satellite Digital Multimedia Broadcasting (SDMB). The gap filler antenna is an antenna that serves as a repeater to transmit a radio wave to a portion where radio waves do not reach.

The signal received from the first antenna 136 passes through the matching (matching) circuit 103 and is separated into a communication frequency signal and a broadcast frequency signal in the diplexer 106.

A single pole double throw (SPDT) switch 109 switches the communication frequency signal from the diplexer 106 to be connected to either the CDMA communication unit 112 or the GSM communication unit 115. That is, the control signal C2 from the control unit 118 switches to connect to the CDMA communication unit 112 or the GSM communication unit 115.

The CDMA communication unit 112 is for processing a CDMA signal and includes a CDMA duplexer and a CDMA RF unit.

The GSM communication unit 115 is for processing a GSM signal and includes a GSM antenna switch and a GSM RF unit.

The first low noise amplifier (LNA) 127 minimizes and amplifies the broadcast frequency signal separated from the diplexer 106 to a level that can be distinguished by the SDMB RF unit 124 in the rear stage. Do this. The second L130 130 minimizes and amplifies the noise of the signal received from the second antenna 139 and passed through the matching (matching) circuit 133.

SDMB (Satellite Digital Multimedia Broadcasting) RF unit 124 receives and demodulates the broadcast signals received from the first LNA 127 and the second LNA 130. In addition, the SDMB RF unit 124 selects a signal having a good level from a signal input through the first antenna 136 to the diplexer 106 and a signal input through the second antenna 139. Diversity function improves reception sensitivity.

The SDMB baseband processor 121 processes the baseband signal passing through the SDMB RF unit 124.

The controller 118 processes the CDMA baseband signal or the GSM baseband signal. On the other hand, in the CDMA mode, the control signal C2 controls the SPDT switch 109 so that the communication frequency signal from the diplexer 106 is connected to the CDMA communication unit 112, and in the GSM mode, the GSM is controlled by the diplexer. The SPDT switch 109 is controlled to be connected to the communication unit 115. In addition, the controller 118 performs a time division duplex (TDD) function by the control signal C1 in the GSM mode.

As described above, in the present invention, both CDMA and GSM are supported so that international roaming services can be used more conveniently with the same terminal abroad. In addition, the 2.6GHz band for the DMB is simultaneously supported, thereby converging broadcasting and communication. It was.

As mentioned above, although this invention was demonstrated to the several example, this invention is not limited to a specific Example. Those skilled in the art will appreciate that various modifications and changes can be made without departing from the spirit of the invention.

As described above, according to the present invention, the conventional mobile communication terminal is equipped with a dual band antenna and an SDMB-only gap filler antenna, so that a roaming service can be used as well as a satellite without having to purchase a separate terminal when traveling abroad or traveling. By enabling the viewing of DMB broadcast has the effect of providing a multi-mode mobile communication terminal for the user to use conveniently.

Claims (6)

In the multi-mode mobile communication terminal operating in GSM mode and CDMA mode, With the first antenna, With a second antenna, A diplexer for separating a communication frequency signal and a broadcast frequency signal from the signal received from the first antenna; An SPDT switch for switching a signal from the diplexer to be connected to one of a CDMA communication unit and a GSM communication unit; A CDMA processor for processing a CDMA signal; A GSM communication unit for processing a GSM signal, A first LNA for minimizing and amplifying noise of a broadcast frequency signal separated from the diplexer; A second LNA which minimizes and amplifies the signal noise received from the second antenna; An SDMB RF unit for demodulating the signals received from the first and second LNAs; SDMB baseband processing unit for processing the baseband signal passing through the SDMB RF unit, Control unit for processing a CDMA baseband signal or a GSM baseband signal, and controls the SPDT switch to be connected to the CDMA communication unit from the diplexer in the CDMA mode, and to control the SPDT switch to be connected to the GSM mode from the diplexer in the GSM mode , Multi-mode mobile communication terminal comprising a. The method of claim 1, The first antenna is a multi-mode mobile communication terminal, characterized in that the dual band antenna covering the 800MHz and 2.6GHz band at the same time. The method of claim 1, The second antenna is a multi-mode mobile communication terminal, characterized in that the gap filler antenna dedicated to SDMB. The method of claim 2, The communication frequency is a multi-mode mobile communication terminal, characterized in that the frequency of the 800MHz band for GSM. The method of claim 2, The broadcast frequency is a multi-mode mobile communication terminal, characterized in that the frequency of the 2.6GHz band for SDMB. The method of claim 1, The SDMB RF unit selects a signal having a good level from a signal input to the diplexer via the first antenna and a signal input to the diplexer via the second antenna to improve reception sensitivity with a diversity function. Multi-mode mobile communication terminal.

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