KR100969310B1 - Radio transceiver system for frequency diversity - Google Patents

Abstract

PURPOSE: A radio transceiver system for frequency diversity is provided to implement frequency diversity in a broadband frequency band efficiently. CONSTITUTION: A local oscillation frequency synthesizing module(100) synthesizes plural independent high frequency subcarriers for frequency diversity, and outputs the synthesized high frequency subcarriers to a transmission-side mixer(200) and a reception mixer(210). An intermediate frequency band and a baseband signal are mixed with the plural high frequency subcarriers from a transmission mixer and the local oscillation frequency synthesizing module. The reception mixer mixes an RF signal with the plural high frequency subcarriers from the local oscillation frequency synthesizing module.

Description

Radio transceiver system for frequency diversity

The present invention relates to a wireless communication system, and more particularly, to a wireless transmission / reception system for implementing frequency diversity.

In the communication using the propagation path via the ionospheric layer or the microwave communication of the sea radio wave, fading is accompanied by a time variation of the received power. Fading results in loss of propagation due to the change in the electrical constant of the medium through which the propagation propagates in time, or the phase difference in which the propagation of each propagation is caused by the strength of the synthesized radio waves transmitted from two or more paths at the same transmission point. This may occur because the interference wave changes in time. This fading affects the change in size of the RCS in applications such as radar systems, and in the signal-to-noise ratio in communication systems.

Such fading has a property that the correlation becomes very small when the reception point, frequency, polarization, and time are changed. Diversity is the use of this property, which includes spatial diversity in which two or more receiving antennas are installed at some distance, frequency diversity in which the same communication information is carried on two or more radio waves having different frequencies, and orthogonal ( polarization diversity using orthogonal wave propagation.

1 is a conceptual diagram of general frequency diversity.

When implementing frequency diversity technology in radar and communication systems, in general, two or more transmission systems are made independently to transmit different frequencies, or one frequency transmission frequency diversity at an intermediate frequency (IF) terminal or baseband is performed by one transmission system. Implement. 1 shows a process of generating f1_RF and f2_RF that are orthogonal to each other by generating different frequencies f1_IF and f2_IF in an intermediate frequency band in one transmission system and mixing them with a high frequency generated by a local oscillation frequency synthesizer.

When implementing frequency diversity with two transmission systems, there is a problem that the transmission system is twice as large and expensive. On the other hand, when implemented in the IF band or the baseband as a single transmission system as shown in Figure 1, because the frequency of the IF band and the baseband is low, because the available frequency range is small, the frequency diversity having a fixed frequency interval or narrow There is a problem that only a few frequency diversity combinations using one frequency interval can be implemented. For example, when f1_IF = 50 MHz and f2_IF = 70 MHz, the frequency interval is only 20 MHz. Accordingly, there is a problem in that an effective frequency diversity using the whole broadband cannot be realized in a communication system having a wide bandwidth.

An object of the present invention is to provide a wireless transmit / receive system for frequency diversity that can effectively implement frequency diversity in a wide frequency band.

In order to solve the above technical problem, the wireless transmission / reception system for frequency diversity according to the present invention synthesizes a plurality of independent high frequency carriers for frequency diversity (diversity) to output to the transmitter and the receiver mixer, respectively Local oscillation frequency synthesis module; A transmitter-side mixer for mixing signals of an intermediate frequency band or a baseband with each of a plurality of high frequency carriers from the local oscillation frequency synthesis module; And a receiver-side mixer for mixing an RF signal with each of a plurality of high frequency carriers from the local oscillation frequency synthesis module.

Here, the local oscillation frequency synthesizing module may sequentially output the plurality of high frequency carriers over time to the transmitter-side mixer.

The local oscillation frequency synthesizing module may simultaneously output the plurality of high frequency carriers to the receiving side mixer.

The local oscillation frequency synthesizing module may include a local oscillation frequency synthesizer configured to synthesize the plurality of high frequency carriers and output them through different output stages; And a switch for switching a connection between each of the different output terminals and the transmitter-side mixer such that the plurality of high-frequency carriers are sequentially output to the transmitter-side mixer over time.

The local oscillation frequency synthesizing module may further include a signal divider configured to divide the high frequency carrier waves from each of the different output terminals and transmit the signal to the switch and the receiver mixer.

According to the present invention described above, by synthesizing a plurality of independent high frequency carriers for frequency diversity in the local oscillation frequency synthesis module, it is possible to effectively implement frequency diversity in a wide frequency band, and to implement a transmission / reception system using one frequency synthesizer. There is an advantage suitable for miniaturization.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the accompanying drawings, substantially the same components are denoted by the same reference numerals, and redundant description will be omitted. In addition, 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 a block diagram of a wireless transmission system for frequency diversity according to an embodiment of the present invention. 3 is an input signal waveform diagram of an intermediate frequency band, FIG. 4 is an output signal waveform diagram of a local oscillation frequency synthesis module, and FIG. 5 is an output signal waveform diagram of a mixer.

A transmission system for frequency diversity according to an embodiment of the present invention includes a local oscillation frequency synthesis module 10 and a mixer 20.

Referring to FIG. 3, a signal of an intermediate frequency band or baseband input to the mixer 20 is a pulse waveform having one center frequency. In other words, frequency diversity is not implemented in an intermediate frequency band or baseband.

The local oscillation frequency synthesis module 10 synthesizes a plurality of independent high frequency (RF) carriers for frequency diversity. Referring to FIG. 4, the local oscillation frequency synthesis module 10 synthesizes carriers having frequencies of orthogonal f1_RF and f2_RF. In other words, frequency diversity is implemented in the local oscillation frequency synthesis module 10. In this case, the plurality of high frequency carriers are sequentially output according to time from one local oscillation frequency synthesis module 10, mixed with signals of an intermediate frequency band or baseband by the mixer 20, and then transmitted separately at different times. .

Referring to FIG. 5, a high frequency signal output from the mixer 20 is a high frequency carrier generated by the local oscillation frequency synthesizing module 10, and a signal of an intermediate frequency band or a base band is loaded, and a transmission signal having a center frequency of f1_RF and f2_RF. to be. The plurality of high frequencies thus formed are transmitted separately through the antenna.

For example, when a signal of an intermediate frequency band having a center frequency of f1 = 100 MHz is input to the mixer 20 and the frequency diversity thereof is to be transmitted, the local oscillation frequency synthesis module 10 transmits f1_RF = 1.6 GHz, Frequency diversity is realized by generating a high frequency carrier of f2_RF = 1.8 GHz. As a result, the output signals of the mixer 20 are orthogonal high frequencies with a center frequency of f1_RF = 1.61 GHz and f2_RF = 1.81 GHz, respectively, and implement frequency diversity in an intermediate frequency band or baseband as mentioned in the background art. Compared to one case, the spacing between the center frequencies is significantly wider. Accordingly, when the communication system according to the present invention is applied to a communication system such as a radar having a wide bandwidth, efficient frequency diversity using the whole broadband can be realized.

6 is a block diagram of a wireless transmission and reception system for frequency diversity according to an embodiment of the present invention. As shown, the wireless transmission / reception system for frequency diversity according to the present embodiment may include a local oscillation frequency synthesis module 100, a transmitter side mixer 200, a receiver side mixer 210, a transmitter module 300, and a receiver module. 400 is made.

The local oscillation frequency synthesis module 100 synthesizes a plurality of independent high frequency carriers having orthogonal frequencies and outputs them to the transmitter-side mixer 200 and the receiver-side mixer 210, respectively. At this time, the local oscillation frequency synthesizing module 100 sequentially outputs a plurality of high frequency carriers to the transmitting side mixer 200 according to time, and simultaneously outputs a plurality of high frequency carriers to the receiving side mixer 210.

The transmitting module 300 generates a signal of an intermediate frequency band or a baseband as a signal to be transmitted, and the transmitting side mixer 200 generates the intermediate frequency band or base on each of a plurality of high frequency carriers from the local oscillation frequency synthesis module 100. Mix the signals in the band. The mixed RF signal is transmitted through the antenna. When the transmission and reception system is a superheterodyne scheme, the transmission module 300 generates a signal of an intermediate frequency band, and when the direct conversion scheme is performed, the transmission module 300 generates a baseband signal.

As described above, since the local oscillation frequency synthesizing module 100 sequentially outputs a plurality of high frequency carriers to the transmitting side mixer 200 according to time, RF signals having different center frequencies orthogonal to each other are sequentially transmitted through the antenna. do.

The receiving mixer 210 mixes RF signals received through an antenna to each of a plurality of high frequency carriers from the local oscillation frequency synthesis module 100. The mixed signal becomes a signal of the intermediate frequency band or the baseband signal. When the transmission and reception system is a superheterodyne method, the mixed signal becomes a signal of an intermediate frequency band, and the receiving module 400 converts the signal of the intermediate frequency band into a signal of the baseband and then performs signal processing. . When the transmission / reception system is a direct conversion method, the mixed signal becomes a baseband signal and the reception module 400 performs signal processing with the baseband signal.

7 shows a specific configuration of the local oscillation frequency synthesis module 100 according to an embodiment of the present invention. The local oscillation frequency synthesis module 100 includes a local oscillation frequency synthesizer 110, first and second signal dividers 120 and 130, and a switch 140, as shown.

The local oscillation frequency synthesizer 110 synthesizes a plurality of independent high frequency carriers having orthogonal frequencies and outputs them through different output stages. That is, when the local oscillation frequency synthesizer 110 synthesizes high frequency carriers of frequencies f1_RF and f2_RF, f1_RF is periodically output to one output terminal and f2_RF to another output terminal. The synthesis of the high frequency carrier may be performed by a direct analog synthesis (DAS) method, a direct digital synthesis (DDS) method, or a combination of analog direct synthesis and digital direct synthesis.

The first signal splitter 120 divides the high frequency carrier of the frequency f1_RF into one signal to the receiving mixer 210 and the other signal to the switch 140 to be described later.

The second signal splitter 130 divides the high frequency carrier of the frequency f2_RF into one signal and transmits one signal to the receiving side mixer 210 and the other signal to the switch 140 to be described later.

The output terminal of the switch 140 is connected to the transmitter side mixer 200, the switch 140 of the local oscillation frequency synthesizer 110 so that a plurality of high frequency carriers are sequentially output to the transmitter side mixer 200 in time. Switch the connection between each of the different output stage and the transmitter side mixer 200. The switching time point is synchronized with the time point at which a plurality of high frequency carriers are output. For example, the local oscillation frequency synthesizer 110 continuously outputs a high frequency carrier of frequency f1_RF and a high frequency carrier of frequency f2_RF through each output terminal, and the switch 140 is synchronized to the period to local oscillation frequency synthesizer 110. When switching between each output terminal and the transmitter side mixer 200, the high frequency carrier of the frequency f1_RF and the high frequency carrier of the frequency f2_RF are alternately output to the transmitter side mixer 200.

On the other hand, since each of the high-frequency carriers signal distribution from the first signal splitter 120 and the second signal splitter 130 is directly transmitted to the receiving side mixer 210, a plurality of high frequency carriers are simultaneously transmitted to the receiving side mixer 210. do. That is, the high frequency carrier of the frequency f1_RF and the high frequency carrier of the frequency f2_RF output from the local oscillation frequency synthesizer 110 are simultaneously transmitted to the receiving mixer 210.

FIG. 8 is a timing diagram illustrating an example in which a transmission signal and a reception signal are transmitted and received in the wireless transmission / reception system for frequency diversity described above. In one embodiment, when the transmission and reception system is applied to the radar system, one period of the transmission and reception interval may be a pulse repetition interval (PRI).

Referring to FIG. 8, the time axis is divided into a transmission section and a reception section. In the transmission section, signals of frequency 1 and frequency 2 are alternately transmitted. In the reception section, signals of frequency 1 and frequency 2 are simultaneously received. This is because the local oscillation frequency synthesis module 100 sequentially outputs the high frequency carrier of the frequency f1_RF and the high frequency carrier of the frequency f2_RF to the transmitting side mixer 200 in time and simultaneously to the receiving side mixer 210. Here, the signal of frequency 1 is a signal in which a high frequency carrier of frequency f1_RF and a signal of an intermediate frequency band (or base band) are mixed, and a signal of frequency 2 is a signal of high frequency carrier and an intermediate frequency band (or base band) of frequency f2_RF. Is the mixed signal. Separation of the transmission section and the reception section is performed according to the signal processing of the transmission module 300 or the reception module 400 (for example, generating an intermediate frequency signal only in the transmission section), except that the reception section is the entire section regardless of the transmission section. It could be

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a conceptual diagram of general frequency diversity.

2 is a block diagram of a wireless transmission system for frequency diversity according to an embodiment of the present invention.

3 is an input signal waveform diagram of an intermediate frequency band, FIG. 4 is an output signal waveform diagram of a local oscillation frequency synthesis module, and FIG. 5 is an output signal waveform diagram of a mixer.

6 is a block diagram of a wireless transmission and reception system for frequency diversity according to an embodiment of the present invention.

7 shows a specific configuration of the local oscillation frequency synthesis module 100 according to an embodiment of the present invention.

FIG. 8 is a timing diagram illustrating an example in which a transmission signal and a reception signal are transmitted and received in the wireless transmission / reception system for frequency diversity described above.

Claims (5)

delete A local oscillation frequency synthesizing module for synthesizing a plurality of independent high frequency carriers for frequency diversity and outputting them to a transmitter mixer and a receiver mixer, respectively; A transmitter-side mixer for mixing signals of an intermediate frequency band or a baseband with each of a plurality of high frequency carriers from the local oscillation frequency synthesis module; And A receiving side mixer for mixing an RF signal with each of a plurality of high frequency carriers from the local oscillation frequency synthesizing module, The local oscillation frequency synthesis module, And transmitting the plurality of high frequency carriers sequentially according to time to the transmitter side mixer. A local oscillation frequency synthesizing module for synthesizing a plurality of independent high frequency carriers for frequency diversity and outputting them to a transmitter mixer and a receiver mixer, respectively; A transmitter-side mixer for mixing signals of an intermediate frequency band or a baseband with each of a plurality of high frequency carriers from the local oscillation frequency synthesis module; And A receiving side mixer for mixing an RF signal with each of a plurality of high frequency carriers from the local oscillation frequency synthesizing module, The local oscillation frequency synthesis module, And wirelessly outputting the plurality of high frequency carriers to the receiving side mixer. The method of claim 2, The local oscillation frequency synthesis module, A local oscillation frequency synthesizer for synthesizing the plurality of high frequency carriers and outputting the same through different output terminals; And a switch for switching a connection between each of the different output terminals and the transmitter-side mixer such that the plurality of high-frequency carriers are sequentially output to the transmitter-side mixer over time. The method of claim 4, wherein The local oscillation frequency synthesis module, And a signal divider for distributing signals of the high frequency carriers from each of the different output terminals and transmitting the signals to the switch and the mixer of the receiving side.

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