KR100353710B1 - Advanced time division duplexing(tdd) type rf signal tx/rx apparatus - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency transceiver of a time division duplexing method, and more particularly, to an apparatus for minimizing an unwanted wave generation problem caused by oscillation frequency of a time division duplexing radio signal transceiver. The present invention is a time division duplexing wireless signal transmission and reception apparatus, comprising: a predetermined control signal according to a radio signal transmission and reception operation, a baseband signal processing unit for outputting predetermined transmission data, and a control signal output from the baseband signal processing unit; Correspondingly, a predetermined band is filtered through a dual divider for dividing the generated radio frequency (RF) oscillation signal by a predetermined multiple and outputting the frequency divided by a predetermined multiple output from the double divider. The baseband signal processor outputs the downconverter for converting the first intermediate frequency signal into a second intermediate frequency signal and outputs the frequency converter signal divided by a predetermined multiple output from the double divider. And a modulator for modulating and outputting data.

Description

Time Division Duplexing Wireless Signal Transceiver {ADVANCED TIME DIVISION DUPLEXING (TDD) TYPE RF SIGNAL TX / RX APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio frequency transceiver of a time division duplexing method, and more particularly, to an apparatus for minimizing an unwanted wave generation problem caused by oscillation frequency of a time division duplexing radio signal transceiver.

In general, a mobile communication terminal adopts a time division duplexing (TDD) scheme in transmitting and receiving radio signals. The structure of the time division duplexing wireless signal transceiver is largely used for transmitting and receiving signals in the uplink and downconversion operation of the frequency, and in the modulation and demodulation of the transmission and reception signals, and the up and down conversion of the signal and the signal It is divided into an oscillator portion that generates an oscillation frequency in the modulation / demodulation process.

A more detailed configuration thereof is shown in FIG. 1.

Referring to FIG. 1, the radio signal received by the antenna 101 is filtered through a RF filter 103 and is applied to the switch 105 after being limited to a predetermined band. In the reception of a radio signal, the switch 105 is switched to a low noise amplifier (LNA) 107 so that the received signal is applied to the LNA 107. This signal is also filtered through the Rx RF filter 109 and applied to a first downconverter 113. The applied signal is subjected to frequency conversion by a predetermined amplified local signal through the Rx local buffer 111, and the converted signal is applied to the first IF filter 115 to filter out the frequency of the required band. It is applied to the second down converter 119. The applied signal is frequency converted again by the output of the Rx IF local transmitter 117 at the second downconverter 119, and the frequency of the band required again by the second IF filter 121 is filtered out. . The signal is applied to the Rx AGC amplifier 123, and the applied signal is amplified or attenuated to a size corresponding to the input level of the demodulator 125. The amplification and attenuation are determined by the Rx AGC voltage generated by the baseband signal processor 131. The signal applied to the demodulator is converted into Rx data and input to the baseband signal processor 131 to perform an analysis process of the received signal.

In the reverse of the radio signal transmission. First, the Tx data generated by the baseband signal processor 131 is applied to the modulator 137, which is modulated by the modulator 137 by the Tx IF local frequency oscillator 139. The modulated signal is filtered into a frequency signal of a band required by the Tx IF filter 141 and then input to the Tx AGC amplifier 143. The signal input to the Tx AGC amplifier 143 is amplified or attenuated by a gain required by the Tx AGC voltage output from the baseband signal processor 131 and applied to the up-converter 145. The signal applied to the up-converter 145 is output after the frequency conversion is performed in the transmission frequency range by the Tx local buffer 147, and the signal that is frequency-converted and output is filtered by the Tx RF filter 149 as a desired signal. After that, it is delivered to a power amplifier (151). The signal amplified and output to the power amplifier 151 is amplified and output to the switch 105, and is transmitted to the antenna 101 via the RF filter 103 by a switching operation of the switch 105. Transmitted wirelessly.

In the transmission and reception operation, the output of the RF local frequency oscillator 157 is synchronized with the output of the reference frequency oscillator 159 through the PLL 155, which is a multiplier 153 and an Rx local buffer 111. And the first down converter 113 and the up converter 145 through the Tx local buffer 147. The PLL data converts the frequency of the RF local frequency oscillator 157 to transmit and receive a signal in a desired frequency band. The multiplier 153 may be changed to an appropriate value according to the frequency environment.

The transceiver shown in the figure is, as mentioned above, an internal configuration commonly used as a TDD transceiver structure.

However, as shown in FIG. 1, in order to transmit and receive a radio signal, frequency up and down, signal modulation and demodulation operations are required. In this case, at least four frequency oscillators are required. It can be seen. However, the use of an excessive frequency oscillator means that the use of multiple frequencies in the transceiver is used. In this case, a problem of undesired waves due to frequency interference occurs, which causes a problem that the transmission / reception performance of the radio signal is degraded. appear.

As a result, it is recommended to use as few frequency oscillators as possible in the TDD radio signal transceiver. However, at present, there has not been proposed an implementation of such a radio signal transmitter / receiver.

It is therefore an object of the present invention to provide such a device in which a frequency oscillator is provided with as little as possible in a time division duplexing wireless signal transceiver to minimize generation of oscillation frequency.

That is, an object of the present invention is to implement a radio time transmission and reception apparatus of the time division duplexing method to minimize the generation of the oscillation frequency.

In order to achieve the above objects, the present invention provides a time division duplexing type wireless signal transmission and reception apparatus, comprising: a baseband signal processing unit for outputting predetermined control signals and predetermined transmission data according to a radio signal transmission and reception operation, and the baseband signal processing unit; Corresponding to the control signal output from the, through the divided frequency divider to generate the radio frequency (RF) oscillation signal generated by a predetermined multiple and outputs, and through the input of the frequency oscillation signal divided by a predetermined multiple output from the double divider, In the baseband signal processing unit through a down converter for converting the first intermediate frequency signal filtered by a predetermined band into a second intermediate frequency signal and outputting the signal, and a frequency oscillation signal divided by a predetermined multiple output from the double divider, Transmitting and receiving further comprising a modulator for modulating and outputting the output data inputted; The value characterized.

1 is a block diagram illustrating a radio signal transceiver of a time division duplexing method according to the prior art.

2 is a block diagram illustrating a radio signal transceiver of a time division duplexing method according to a first embodiment of the present invention.

3 is a diagram illustrating an internal configuration of a wireless signal transceiver of a time division duplexing method according to a second embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. Also, in the following description, many specific details such as components of specific circuits are shown, which are provided to help a more general understanding of the present invention, and the present invention may be practiced without these specific details. It is self-evident to those of ordinary knowledge in Esau. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

2 is an internal configuration diagram of a time division duplexing wireless signal transceiver according to a first embodiment of the present invention, and FIG. 3 is a diagram illustrating an internal configuration of a time division duplexing wireless signal transceiver according to another preferred embodiment of the present invention. It is a block diagram.

First, the configuration of the present invention will be described with reference to FIG. 2.

First, as described above with reference to FIG. 1, in the configuration of FIG. 2, the signal received by the antenna 101 filters only the received signal of a desired band through the RF filter 103, and thus the low noise amplifier through the switch 105. 107 is applied. Thereafter, the signal applied to the low noise amplifier 107 is amplified and then filtered again by the Rx RF filter 109 and applied to the first down converter 113. The applied signal is converted into a first intermediate frequency (IF) signal according to an input of a signal amplified in the RF local buffer 111 after the output of the RF local frequency oscillator 157 is multiplied P times in the multiplier 153. The frequency is converted and output. The output signal is filtered by the first IF filter 115 and then applied to the second down converter 119. The applied signal is converted into a second IF frequency signal by a signal input to the second down converter 119, that is, a signal in which an RF frequency oscillator 157 is divided by N + 1. The N + 1 divided signal is output from the 1 / N, 1 / (N + 1) double divider 201 provided in the practice of the present invention, which is the Tx generated from the baseband signal processor 131. The / Rx signal is outputted by being applied to the double divider 201. In the operation at the time of radio signal reception, the double divider 201 is characterized in that the division operation is performed at 1 / (N + 1). The second IF frequency signal converted and output according to such an operation is filtered by the second IF filter 121 and applied to the Rx AGC amplifier 123. Then, the applied signal is amplified or attenuated into an appropriate signal in demodulation according to the input of the Rx AGC signal generated by the baseband signal processing unit 131, and output. The amplified or attenuated signal is demodulated through a demodulator 125 and output as Rx data, which is input to the baseband signal processor 131 to perform an analysis process of a received signal.

On the contrary, the radio signal transmission operation in the practice of the present invention is performed as follows.

First, the Tx data generated by the baseband signal processor 131 is input to the modulator 137 and modulated. The modulation process is performed by inputting a signal divided by N in the double divider 201. The double divider 201 performs an operation with a 1 / N divider at the time of transmission. That is, the 1 / N, 1 / (N + 1) double divider 201 provided in the practice of the present invention transmits a radio signal according to the application of the Tx / Rx signal generated from the baseband signal processing unit 131. Dispensing will be done at hour 1 / N. The modulated signal is filtered by the Tx IF filter 141 and then input to the Tx AGC amplifier 143. The TX AGC amplifier 143 amplifies or attenuates the input signal according to the application of the Tx AGC signal output from the baseband signal processor 131. At this time, the amplification or attenuation is made of the size of the signal corresponding to the desired output, the amplified or attenuated signal is applied to the up-converter (145). The up-converter 145 frequency converts the applied signal to a transmission frequency band by a local signal input through the Tx local buffer 147. Here, the frequency-converted signal is filtered by the Tx RF filter 149, inputted to the power amplifier 151, amplified, and through the antenna 101 through the RF filter 103 through a switching operation of the switch 105. Transmitted wirelessly.

On the other hand, in the above description of the operation, the double divider 201 performs the N + 1 division operation in the reception processing of the radio signal and determines the N division processing in the transmission processing of the radio signal. Depending on the application, even if they are implemented opposite to each other in the practice of the present invention.

As a result, in the practice of the present invention, it can be seen that the number of frequency oscillators is smaller than that of other radio signal transceivers in the prior art as shown in FIG.

The principle of the radio signal transmitting and receiving device shown in FIG. 3 is also the same.

In particular, the apparatus for transmitting and receiving a radio signal of the configuration shown in FIG. 3 is a configuration that is applied when the modulation of the FSK series is performed, which inputs and modulates Tx data to the RF local frequency oscillator 157, and the modulated signal After the N division through the double divider 201, except that the operation to apply to the Tx IF filter 141 performs the same signal processing as the radio signal transmitting and receiving device shown in FIG. In FIG. 3, the reference frequency oscillator 159 and the PLL 155 are used to phase-lock the reference oscillation signal of the RF local frequency oscillator.

Hereinafter, a state in which the configuration described in FIG. 2 is applied to an actual wireless signal transceiver is implemented.

The state in which the present invention is implemented in a wireless LAN of 2.4 GHz band, which is used in recent years, will be described. The wireless LAN also becomes a TDD wireless signal transceiver. It uses frequencies in the 2.4 to 2.48 GHz band. In this case, the multiplier P of the multiplier 153 is 2, and N of the double divider 201 is 10. Then, in the transmission of the radio signal, the modulation frequency input to the modulator 137 has P of 2 and N of 10, so that the frequency corresponding to 1/21 of the transmission frequency of 2.4 GHz to 2.38 GHz is about 114.285714 MHz to 118.095238 MHz. In the reception process, the output frequency of the RF local buffer 111 input to the first downconverter 113 is 114.285714 MHz to 118.095238 MHz, and the first IF frequency is 114.285714 MHz to 118.095238 MHz, and the second downconverter ( The local frequency input to 119 is 103.89613 MHz to 107.3593074 MHz, and the second IF frequency range is about 10.389611 MHz to 10.7359306 MHz. Therefore, the transmit / receive frequency range is about 80 MHz while the second IF frequency range is only about 346.32 KHz. Even though the transmit / receive frequency range is 80 MHz, it is not a big problem to filter in the second IF filter. Is done. In other words, it does not significantly affect the adjacent channel.

Similarly, in the radio signal transceiver according to the configuration of FIG. 3, the same signal as the operation of the transceiver shown in FIG. 2 is used except that the RF local frequency oscillator 157 directly processes the Tx data in modulation. Perform the process.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

After all, as can be seen from the above, in the apparatus using the TDD transmission and reception method, at least four or more frequency oscillators should be provided through the conventional method, but through the implementation of the present invention, about two frequency oscillators The provision has the advantage of achieving the same operation.

This also shows the advantage of being able to solve the problem of generation of unwanted waves due to the frequency mutual interference for the provision of a plurality of frequency oscillators, and the problem of deterioration in the transmission and reception performance of the radio signal by such unwanted waves.

And through the implementation of the present invention, in laying out the wireless signal transceiver to the PCB, there is no need for a separate design to reduce the effect of interference.

Claims (8)

In the time division duplexing wireless signal receiving apparatus, A baseband signal processor for outputting a predetermined control signal according to a radio signal reception operation; A double divider for dividing the generated radio frequency (RF) frequency oscillation signal by a predetermined multiple in response to the control signal, and outputting the divided frequency; And a down converter converting the first intermediate frequency signal filtered by a predetermined band into a second intermediate frequency signal through the input of a frequency oscillation signal divided by a predetermined multiple output from the double divider. Device. The method of claim 1, wherein the double divider, According to the reception state of the radio signal, characterized in that the frequency oscillation signal generated by selecting 1 / N or 1 / (N + 1) to divide and output the device. In the time division duplexing wireless signal transmission apparatus, A baseband signal processor for outputting predetermined control signals and predetermined transmission data according to a radio signal transmission operation; A double divider which selects and divides the generated radio frequency (RF) frequency oscillation signal in a predetermined multiple in response to the control signal; And a modulator for modulating and outputting transmission data output from the baseband signal processor by inputting a frequency oscillation signal divided by a predetermined multiple output from the double divider. The method of claim 3, wherein the double divider, According to the transmission state of the radio signal, characterized in that the frequency oscillation signal generated by 1 / N or 1 / (N + 1) to divide and output the device. The method of claim 3, wherein the double divider, And a modulated signal generated by being modulated according to the transmission data output from the baseband signal processor by a predetermined multiple. In the time division duplexing wireless signal receiving apparatus, A frequency oscillator for generating and outputting a predetermined frequency oscillation signal; A multiplier for multiplying the output frequency oscillation signal by a predetermined multiple so that the low noise amplified and filtered radio signal is converted into a first intermediate frequency signal, and And a dual divider for dividing the output frequency oscillation signal by a predetermined multiple so as to convert the first band frequency filtered signal to a second intermediate frequency signal. In the time division duplexing wireless signal transmission apparatus, A frequency oscillator for generating and outputting a predetermined frequency oscillation signal; A dual divider for dividing the output frequency oscillation signal by a predetermined multiple so as to modulate and output transmission data input by processing a predetermined baseband signal; And a multiplier for multiplying and outputting the output frequency oscillation signal by a predetermined multiple so that the predetermined amplified and attenuated modulated signal is converted to a transmission frequency band after the predetermined band filtering. In the time division duplexing wireless signal transmission apparatus, A frequency oscillator for generating and outputting a frequency oscillation signal in a state modulated by a predetermined baseband signal processed input data; A double divider for dividing and outputting the frequency oscillating signal in the modulated state by a predetermined multiple; And a multiplier for multiplying and outputting the output frequency oscillation signal by a predetermined multiple so that the predetermined amplified and attenuated signal in the divided state is converted into a transmission frequency band after being filtered by a predetermined band. .