KR20090005038U - Multi-band tranceiver - Google Patents

Abstract

Multi-band transceiver according to an embodiment includes a first signal separation unit for transmitting a first transmission signal to the first amplifier, and a second transmission signal to the second amplifier; A second signal separator selectively transferring the first transmission signal amplified by the first amplifier and the second transmission signal amplified by the second amplifier to a first antenna; A third signal separator for transmitting a first received signal from a signal received from the first antenna to a first filter, and a second received signal to a second filter; And a fourth signal splitter configured to selectively transfer the first received signal filtered by the first filter and the second received signal filtered by the second filter to a first low noise amplifier.

According to the embodiment, by simultaneously processing a multi-band channel signal such as WiMAX, it is possible to provide a communication service differentiated according to the channel signal using a single terminal. In addition, since the multi-channel channel signal can be processed through one front end without configuring a plurality of front end stages, there is an effect of minimizing circuit size and minimizing interference between devices.

Multiband Transceivers, Low Noise Amplifiers, Filters, Power Amplifiers, WiMAX, WiBro

Description

Multi-Band Transceiver

An embodiment discloses a multiband transceiver.

Recently, the WiMAX (Wireless Worldwide Interoperability for Microwave Access), which uses a broadband frequency of 2.3GHz or more, has attracted much attention both at home and abroad due to its low cost of installing large data communications and networks compared to existing telecommunication networks.

WiMAX is receiving a lot of attention from fixed WiMAX (802.16-2004 standard) and mobile WiMAX (802-16e standard) based on the IEEE 802.16 standard, and related communication technologies are being developed.

WiBro (WIBRO), which currently provides services based on KT in Korea, is the same concept as WiMAX, and is based on the IEEE 802.16e standard and is used in mobile mobile communication devices with guaranteed mobility.

The mobile WiMAX performs communication using various frequency channels such as 2.3 GHz band and 2.5 GHz band, and the fixed WiMAX performs communication using various frequency channels such as 3.5 GHz band and 5.8 GHz band.

Mobile communication devices using mobile WiMAX are largely divided into baseband stage RF transceiver stages based on MAC and PHY. Among them, the RF transceiver stage is composed of RFIC (Radio Frequency Integrated Circuit) stage and front end stage. .

While the chip product of the RF IC stage supports all of the various channel signals described above, the front end stage is configured by mounting individual components such as a power amplifier, a low noise amplifier, a filter, and a switch circuit, thereby selecting one frequency channel signal. There is no choice but to deal with it.

For example, a domestic mobile mobile communication device is manufactured to process only a signal of about 2.3 GHz band, and a mobile mobile communication device for overseas use is manufactured to process only a signal of about 2.5 GHz band.

In addition, when the front end stage is configured to process a plurality of channel signals, a plurality of front end stages must be implemented according to each signal path, and thus there is a problem such as a large circuit size and interference between devices.

The embodiment provides a transceiver for a mobile communication device that can simultaneously process a channel signal having multiple bands, such as WiMAX.

Multi-band transceiver according to an embodiment includes a first signal separation unit for transmitting a first transmission signal to the first amplifier, and a second transmission signal to the second amplifier; A second signal separator selectively transferring the first transmission signal amplified by the first amplifier and the second transmission signal amplified by the second amplifier to a first antenna; A third signal separator for transmitting a first received signal from a signal received from the first antenna to a first filter, and a second received signal to a second filter; And a fourth signal splitter configured to selectively transfer the first received signal filtered by the first filter and the second received signal filtered by the second filter to a first low noise amplifier.

According to the embodiment, the following effects are obtained.

First, by simultaneously processing a multi-band channel signal such as WiMAX, it is possible to provide a communication service differentiated according to the channel signal using a single terminal.

Second, multi-channel channel signals can be processed through one front end without configuring a plurality of front end stages, thereby minimizing circuit size and minimizing interference between devices.

With reference to the accompanying drawings, a multi-band transceiver according to an embodiment will be described in detail.

1 is a block diagram schematically illustrating the components of a multi-band transceiver 200 according to an embodiment.

The multi-band transceiver 200 according to the embodiment processes the WiMAX signal. The WiMAX will be briefly described as follows.

WiMAX is a method developed for the technical standard of wireless high speed communication and is defined by the IEEE 802.16 standard.

WiMAX stands for "Worldwide Interoperability for Microwave Access," and refers to authentication of equipment that meets the 802.16-based standard. This is divided into fixed WiMAX based on the IEEE 802.16-2004 standard and Mobile WiMAX of the IEEE 802.16e standard. Dual WiMAX can transmit data at speeds up to 15 Mbit / s in a radius of about 3 km.

Referring to FIG. 1, the multi-band transceiver 200 according to the embodiment includes an RF IC stage 280 and a front end stage 290, and the front end stage 290 includes a first signal separator ( 235, the second signal separation unit 205, the third signal separation unit 210, the fourth signal separation unit 240, the fifth signal separation unit 255, the sixth signal separation unit 270, and the first signal separation unit 205. A power amplifier (PA) 215, a second amplifier 220, a first filter 225, a second filter 230, a third filter 260, a fourth filter 265, and a fifth filter ( 245), a first low noise amplifier (LNA) 250, and a second low noise amplifier 275.

The multi-band transceiver 200 according to the embodiment may process a WiMAX signal of a multi-band, for example, a mobile WiMAX signal of 2.3 GHz band and 2.5 GHz band or a fixed WiMAX signal of 3.5 GHz band and 5.8 GHz band. can do.

In an embodiment, the multi-band transceiver 200 is mounted on a mobile communication terminal and processes a mobile WiMAX signal.

For convenience of description, the WiMAX received signal in the 2.3 GHz band is referred to as a "first receive signal", and the WiMAX transmit signal in the 2.3 GHz band is referred to as a "first transmit signal".

In addition, a WiMAX received signal in the 2.5 GHz band is referred to as a "second received signal", and a WiMAX transmitted signal in the 2.5 GHz band is referred to as a "second transmitted signal".

The first filter 225 to the fifth filter 245 may be provided as a SAW filter.

The Saw filter converts an input signal, which is an electromagnetic wave of light, into a surface acoustic wave, which is a low-speed acoustic wave, and then extracts only the frequency of the required wavelength, and has a narrow bandwidth and a good selection characteristic. . In addition, the saw filter is designed with high VSWR characteristics in the cut-off frequency band and minimizes the loss due to band combining.

The first filter 225 and the third filter 260 are designed to filter the first received signal, and the second filter 230 and the fourth filter 265 are designed to filter the second received signal.

The fifth filter 245 is designed to satisfy both frequency bands of the first transmission signal and the second transmission signal transmitted from the RF IC stage 280, and removes a signal of noise component generated in the modulation process.

In an embodiment, the first signal separator 235 to the sixth signal separator 270 may be implemented as a diplexer.

The first signal separator 235, the third signal separator 210, and the fifth signal separator 255 output one input signal as two signals, and the second signal separator 205. The fourth signal separator 240 and the sixth signal separator 270 output two input signals as one signal.

Hereinafter, operations of the signal separators 235, 205, 210, 240, 255, and 270 having such a connection configuration will be described.

The first signal separator 235 transfers the first transmission signal filtered by the fifth filter 245 to the first amplifier 215, and transfers the second transmission signal to the second amplifier 220.

The second signal separator 205 selectively transfers the first transmission signal amplified by the first amplifier 215 and the second transmission signal amplified by the second amplifier 220 to the first antenna 201. do.

The first antenna 201 transmits the first transmission signal or the second transmission signal.

On the other hand, the third signal separator 210 transmits a first received signal among the signals received from the first antenna 201 to the first filter 225, and transmits a second received signal to the second filter 230. To pass.

The fourth signal separator 240 selectively converts the first received signal filtered by the first filter 225 and the second received signal filtered by the second filter 230 to the first low noise amplifier 250. To pass.

The first low noise amplifier 250 low noise amplifies the first received signal or the second received signal transmitted from the fourth signal separator 240 and transmits the low noise amplifier to the RF IC stage 280.

The first low noise amplifier 250 is designed by catching an operating point and a matching point such that a noise figure has a small value, and noise according to an ACPR (Adjacent Channel Power Ratio) rule defining a linear characteristic of an amplification operation. Exclude the component and amplify only the signal in that band.

The multi-band transceiver 200 according to the embodiment may not only process the WiMAX signal of the multi-band but also process the received signal in a spatial diversity manner. The fifth signal separator 255 and the third filter 260 ), The fourth filter 265, the sixth signal separator 270, and the second low noise amplifier 275 are components that process diversity signals.

The fifth signal separator 255, the third filter 260, the fourth filter 265, the sixth signal separator 270, and the second low noise amplifier 275 are each the third signal separator 210. ), The first filter 225, the second filter 230, the fourth signal separator 240, and the first low noise amplifier 250 correspond to an operation of processing the first received signal and the second received signal. similar.

Hereinafter, repeated descriptions will be omitted.

The second antenna 202 is located at a different position from the first antenna 201, and receives the first and second reception signals received through the second antenna 202 and transmitted to the fifth signal separation unit 255. The signal is a spatially diversity signal.

On the other hand, the signal transmitted and received through the first antenna 201 is the main signal.

The RF IC stage 280 may be implemented as a single chip device, and includes a modulation / demodulation circuit.

The RF IC stage 280 modulates the first transmission signal or the second transmission signal, which is generated as a digital signal, into an RF state and transmits the RF signal to the fifth filter 245.

In addition, the RF IC stage 280 demodulates the first received signal or the second received signal transmitted from the first low noise amplifier 250 and the second low noise amplifier 275 from the RF state to the digital state.

The RF IC stage 280 may include a first main received signal or a second main received signal transmitted from the first low noise amplifier 250 and a first diversity received signal transmitted from the second low noise amplifier 275 or the like. By comparing and analyzing the second diversity reception signal, it is possible to stably restore the data.

The RF IC stage 280 may include a control circuit. The control circuit sets an operation method of the multi-band transceiver 200 according to an embodiment and applies a control voltage to the first signal separator 235. ) To the signal splitting operation of the sixth signal splitter 270.

2 illustrates a multi-band transceiver 100 when the signal separators 235, 205, 210, 240, 255, and 270 are implemented as switching elements 135, 105, 110, 140, 155, and 170. It is a block diagram schematically showing the components of.

Referring to FIG. 2, the first signal separator 235 to the sixth signal separator 270 described with reference to FIG. 1 may include the first switching element 135, the second switching element 105, and the third switching, respectively. The device 110, the fourth switching device 140, the fifth switching device 155, and the sixth switching device 170 may be provided to connect the switching devices 135, 105, 110, 140, 155, and 170. And the operation is the same as the signal separator 235, 205, 210, 240, 255, 270.

As the first switching element 135 to the sixth switching element 170, a switching element implemented with a semiconductor chip may be used.

In addition, the first amplifier 115, the second amplifier 120, the first filter 125, the second filter 130, the third filter 160, the fourth filter 165, and the fifth filter 145. The first low noise amplifier 150, the second low noise amplifier 175, and the RF IC stage 180 have the same connection configuration and operation as those described with reference to FIG. 1.

Therefore, repeated description will be omitted.

The present invention has been described above with reference to the preferred embodiments, which are merely examples and are not intended to limit the present invention, and those skilled in the art to which the present invention pertains do not depart from the essential characteristics of the present invention. It will be appreciated that various modifications and applications are not possible that are not illustrated above. 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.

1 is a block diagram schematically illustrating components of a multi-band transceiver according to an embodiment.

2 is a block diagram schematically illustrating the components of a multi-band transceiver when the signal separation unit according to the embodiment is implemented as a switching element.

Claims (7)

A first signal separation unit transferring the first transmission signal to the first amplifier and the second transmission signal to the second amplifier; A second signal separator selectively transferring the first transmission signal amplified by the first amplifier and the second transmission signal amplified by the second amplifier to a first antenna; A third signal separator for transmitting a first received signal from a signal received from the first antenna to a first filter, and a second received signal to a second filter; And a front end end including a fourth signal separator for selectively transferring the first received signal filtered by the first filter and the second received signal filtered by the second filter to a first low noise amplifier. The method of claim 1, wherein the front end is A fifth signal separation unit configured to transfer a first received signal from a signal received from the second antenna to a third filter, and to transfer the second received signal to a fourth filter; And a sixth signal splitter configured to selectively transfer the first received signal filtered by the third filter and the second received signal filtered by the fourth filter to a second low noise amplifier. The method of claim 1, The first transmission signal and the first reception signal are WiMAX signals in a 2.3 GHz band, the second transmission signal and the second reception signal are WiMAX signals in a 2.5 GHz band, And the first transmission signal and the first reception signal are WiMAX signals in a 3.5 GHz band, and the second transmission signal and the second reception signals are WiMAX signals in a 5.8 GHz band. The method of claim 1, Modulating the first transmission signal or the second transmission signal from a digital state to an RF state and transmitting the first transmission signal or the second transmission signal to the first signal separation unit, and transmitting the first or second reception signal transmitted from the fourth signal separation unit to the RF state. A multiband transceiver comprising an RF IC stage that demodulates to digital state in the circuit. The method of claim 2, Modulating the first transmission signal or the second transmission signal from a digital state to an RF state and transmitting the first transmission signal or the second reception signal to the first signal separation unit, and transmitting the first reception signal or the second reception signal transmitted from the sixth signal separation unit to an RF state. A multiband transceiver comprising an RF IC stage that demodulates to digital state in the circuit. The method of claim 1, And a fifth filter connected to an input terminal of the first signal separator. The method of claim 2, wherein at least one of the first signal separator to the sixth signal separator Multiband transceiver implemented as a switching element or diplexer.

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