KR20120031763A - Orthogonal frequency division modulation module and ultra wide band transmitter using the module - Google Patents

Abstract

PURPOSE: An orthogonal frequency division modulation module and an UWB(Ultra Wide Band) transmitter using the same are provided to reduce the use frequency band of each frequency MUX(Multiplexer) by supplying one frequency MUX to each group. CONSTITUTION: A UWB(Ultra Wide Band) transmitter(100) comprises a modulator(110), a data deserializer(120), an orthogonal frequency division modulation module(130), a power amplifier(140), and an antenna(150). The modulator generates modulation transmission data by modulating transmission data. The data deserializer changes the modulation transmission data serially inputted into a plurality of transmission data. The orthogonal frequency division modulation module generates a radio frequency signal by performing orthogonal frequency division multiplexing for a plurality of transmission data parallely inputted. The power amplifier amplifies the radio frequency signal. The antenna transmits an amplified radio frequency signal to the air.

Description

Orthogonal Frequency Division Modulation Module and Ultra Wide Band Transmitter using the Module

The present invention relates to an orthogonal frequency division modulation module, and more particularly, to an orthogonal frequency division modulation module for performing frequency mixing by dividing a plurality of intermediate frequency subcarrier signals into at least two groups.

In general, UWB OFDM (Ultra Wide Band Orthogonal Frequency Division Modulation) technology processes an entire subcarrier signal in one frequency mixer over an entire band of intermediate frequency (IF). The frequency mixer converts low and high frequencies to each other, and is generally implemented using a transistor or a diode. If the frequency range of the signal in which the frequency mixer is used is too wide due to the frequency characteristics of the transistors and diodes, the electrical characteristics of the frequency mixer are deteriorated.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an orthogonal frequency division modulation module that enables the use of a frequency mixer that does not have excellent electrical characteristics with respect to frequency.

Another technical problem to be solved by the present invention is to provide a ＵＷＢ transmitter using an orthogonal frequency division modulation module that enables the use of a frequency mixer that is not excellent in electrical characteristics with respect to frequency.

An orthogonal frequency division modulation module according to an aspect of the present invention for achieving the above technical problem includes N ODF blocks and a first adder. The N ODFM blocks divide a plurality of data input in parallel into a group of N (N is a natural number of 2 or more), and a plurality of subcarrier signals and a local having a plurality of data belonging to each group having different frequency characteristics. Orthogonal frequency division modulation using the oscillation signal generates N sub-RF signals. The first adder sums the N sub-RF signals to generate an RF signal.

According to another aspect of the present invention for achieving the above technical problem, an orthogonal frequency division modulation module includes a first orthogonal frequency division modulation block, a second orthogonal frequency division modulation block, and a first adder. The first orthogonal frequency division modulation block performs orthogonal frequency division modulation on 64 of 128 data input in parallel using 64 subcarrier signals and 128 local oscillation signals among 128 subcarrier signals. Generate a first RF signal. The second orthogonal frequency division modulation block generates a second RF signal by performing orthogonal frequency division modulation on the remaining 64 data using the remaining 64 subcarrier signals and the local oscillation signal. The first adder adds the first RF signal and the second RF signal to generate an RF signal.

According to an aspect of the present invention for achieving the another technical problem, the W transmitter performs a function of propagating the modulated transmission data by RF orthogonal frequency division modulation to the RF signal, a data serial-parallel converter, orthogonal frequency division modulation module and antenna It is provided. The data serial-to-parallel converter converts the modulated transmission data input in series into a plurality of parallel data. The orthogonal frequency division modulation module generates orthogonal frequency division modulation on the plurality of parallel data to generate a transmission signal. The antenna propagates the transmission signal to the air. The orthogonal frequency division modulation module includes N ODF blocks and a first adder. The N ODM blocks divide the plurality of parallel data into groups of N (N is a natural number of 2 or more), and the plurality of subcarriers and local oscillation signals having different frequency characteristics are divided into a plurality of data belonging to each group. Orthogonal frequency division modulation is used to generate N sub-RF signals. The first adder adds the N sub-RF signals to generate the transmission signal.

According to another aspect of the present invention for achieving the above technical problem, the transmitter comprises a function of orthogonal frequency division modulation of the modulated transmission data into an RF signal to propagate to the air, a data serial-parallel converter, an orthogonal frequency division modulation module, and With an antenna. The data serial-to-parallel converter converts the input modulation transmission data into 128 parallel data. The orthogonal frequency division modulation module generates orthogonal frequency division modulation on the 128 parallel data to generate a transmission signal. The antenna propagates the transmission signal to the air. The orthogonal frequency division modulation module includes a first orthogonal frequency division modulation block, a second orthogonal frequency division modulation block, and a first adder. The first orthogonal frequency division modulation block performs orthogonal frequency division modulation on 64 data among the 128 data input in parallel using 64 subcarrier signals and a local oscillation signal among 128 subcarrier signals. Generate a first RF signal. The second orthogonal frequency division modulation block generates orthogonal frequency division modulation on the remaining 64 data using the remaining 64 subcarrier signals and the local oscillation signal to generate a second RF signal. The first adder sums the first RF signal and the second RF signal to generate the transmission signal.

The present invention has an advantage in that a UWB system having excellent electrical performance can be implemented by using a frequency mixer having excellent electrical characteristics with respect to frequency.

1 is a block diagram of a UWB transmitter with an orthogonal frequency division modulation module in accordance with the present invention.
FIG. 2 is an internal circuit diagram of the orthogonal frequency division modulation module 130 shown in FIG. 1.
3 is an example of a frequency mixer used in the transmitter.
4 is an example of a frequency mixer used in the receiver.
5 is an embodiment of a single balanced mixer.
6 is an embodiment of a double balanced mixer.
7 is an internal circuit of an orthogonal frequency division modulation module according to the present invention.

In order to fully understand the present invention and the operational advantages of the present invention and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings, which are provided for explaining exemplary embodiments of the present invention, and the contents of the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

The core idea of the present invention is to divide a plurality of intermediate frequency subcarrier signals used for orthogonal frequency division modulation into at least two groups, and to generate a subcarrier signal and transmission data in each group. A frequency mux for muxing the mixed signal and the local oscillation signal is provided in each group. This reduces the frequency band in which each frequency mux is used.

1 is a block diagram of a UWB transmitter with an orthogonal frequency division modulation module in accordance with the present invention.

Referring to FIG. 1, the UWB transmitter 100 includes a modulator 110, a data serial-parallel converter 120, an orthogonal frequency division modulation module 130, a power amplifier 140, and an antenna 150.

The modulator 110 modulates the transmission data DATA to generate modulated transmission data X _n . The data serial-to-parallel converter 120 converts serially-modulated transmission data X _n into a plurality of transmission data X ₀ to X _{N -1} . The orthogonal frequency division modulation module 130 generates radio frequency (RF) signals by performing orthogonal frequency division modulation on the plurality of transmission data X ₀ to X _{N −1} input in parallel. The power amplifier 140 amplifies a radio frequency (RF) signal. The antenna 150 transmits the amplified radio frequency (RF) signal to the air.

FIG. 2 is an internal circuit diagram of the orthogonal frequency division modulation module 130 shown in FIG. 1.

Referring to FIG. 2, each of the plurality of transmission data X ₀ to X _{N -1} is frequency-mixed in the corresponding subcarrier signals f ₀ to f _{N -1} and the subcarrier frequency mixers 201 to 203, respectively. The plurality of frequency mixed signals are combined in the adder 210. The output signal x (t) of the adder may be expressed as in Equation 1.

The output of the adder 210 is frequency mixed in the local oscillation signal F _LO and the radio frequency mixer 220 to generate a transmission signal RF. The frequency of the local oscillation signal f _LO is higher than the frequencies of the subcarrier signals f ₀ to f _N-1 .

Hereinafter, a frequency mixer will be described for better understanding of the invention.

3 is an example of a frequency mixer used in the transmitter.

Referring to FIG. 3, the frequency mixer 301 used in the transmitter generates a radio frequency signal f _RF by mixing an intermediate frequency signal f _IF and a local oscillation signal f _LO output from the local oscillator 302. do.

The generated radio frequency signal f _RF may be expressed as in Equation 2.

Since the frequency of the local oscillation signal f _LO is higher than the frequency of the intermediate frequency signal f _IF , it can be seen that the frequency is converted by passing through the mixer.

In this case, the frequency conversion means that only the frequency is changed while maintaining the information contained in the signal on the time axis. Another meaning in the frequency spectrum is that the center frequency of the signal has shifted.

4 is an example of a frequency mixer used in the receiver.

Referring to FIG. 4, the frequency mixer 401 used in the receiver generates an intermediate frequency signal f _IF by mixing a radio frequency signal f _RF and a local oscillation signal f _LO output from the local oscillator 402. do.

The generated intermediate frequency signal f _IF may be expressed as in Equation 3.

As can be seen in Figures 3 and 4, the frequency mixer performs a function of mixing the two frequencies to generate a frequency corresponding to the sum or difference. Frequency mixers are usually divided into active frequency mixers implemented using transistors and passive frequency mixers implemented using diodes.

Important electrical characteristics that govern the performance of a frequency mixer include the dynamic range and the noise figure. While the input and output signals of the frequency mixer exhibit certain characteristics, the loss increases when the power exceeds a certain limit. The dynamic range refers to the range of the difference between the maximum power and the minimum power available to the frequency mixer. This is due to the nonlinear nature of the devices used to implement the frequency mixer. The noise figure is defined as the ratio of the input signal to noise divided by the output signal to noise ratio. A frequency mixer implemented using devices that have nonlinear characteristics with respect to frequency needs to have a noise figure below a certain value.

Due to the nonlinear characteristics of the frequency mixer, the frequency range of the signal converted in the frequency mixer is limited. If the frequency range is exceeded, the noise figure is lowered. It is obvious that the noise contained in the signal output from the frequency mixer will degrade the performance of the entire system using the frequency mixer.

5 is an embodiment of a single balanced mixer.

6 is an embodiment of a double balanced mixer.

5 and 6, all signal ports of a single balanced mixer and a double balanced mixer are processed in the form of a balanced signal divided into a positive signal and a negative signal. Since the transistors T1 to T9 shown in FIGS. 5 and 6 themselves are nonlinear devices, the frequency of the input / output signal is limited as described above. Therefore, as illustrated in FIG. 2, it is problematic to frequency-mix signals in the entire frequency domain including subcarrier signals f ₀ to f _N-1 using one frequency mixer 220.

Hereinafter, an orthogonal frequency division modulation module proposed by the present invention will be described. For ease of understanding, the number of modulation transmission data is limited to 128 and the number of subcarrier signals is also limited to 128.

7 is an internal circuit of an orthogonal frequency division modulation module according to the present invention.

Referring to FIG. 7, an orthogonal frequency division modulation module according to the present invention includes a first FDM block 710, a second OFDM block 720, and a first adder 730.

The first FDM block 710 and the second OFDM block 720 divide the ₁₂₈ modulation transmission data (X ₁ to X ₁₂₈ ) into two equal parts and perform orthogonal frequency division modulation on 64 modulation transmission data, respectively. The first adder 730 generates a radio frequency signal RF by adding the signals output from the first FDM block 710 and the second OFDM block 720.

The first OFDM block 710 includes 64 first subcarrier frequency mixers 711-713, a second adder 714, and a first radio frequency mixer 715. Each of the 64 first subcarrier frequency mixers 711 to 713 includes 64 modulation transmission data X ₁ to X ₆₄ and 64 sub carrier frequency signals f _1. f ₆₄ ). The second adder 714 sums signals output from the 64 first subcarrier frequency mixers 711 to 713. The first radio frequency mixer 715 may frequency-mix the signal output from the second adder 714 and the local oscillator signal f _LO output from a local oscillator (not shown) to perform a first sub-radio frequency signal ( S1_RF).

The second OFDM block 720 includes 64 second subcarrier frequency mixers 721-723, a third adder 724, and a second radio frequency mixer 725. Each of the 64 second subcarrier frequency mixers 721 to 723 frequency-mixes 64 modulated transmission data X ₆₅ to X ₁₂₈ and 64 subcarrier frequency signals f ₆₄ to f ₁₂₈ . The third adder 724 sums signals output from the 64 second subcarrier frequency mixers 721 to 723. The second radio frequency mixer 725 is frequency-mixed with the signal output from the third adder 724 and the local oscillation signal f _LO output from a local oscillator (not shown) to form a second sub-radio frequency signal ( S2_RF).

The first adder 730 combines the first sub-radio frequency signal S1_RF and the second sub-radio frequency signal S2_RF to generate a radio frequency signal RF.

As described above, since the radio frequency mixers 715 and 725 according to the present invention operate only in a frequency band of 1/2 of the frequency bands of the entire subcarrier frequency signals, the radio frequency mixer 220 shown in FIG. It is easily understood that the dynamic range and the noise figure are excellent.

In FIG. 7, the frequency bands of the entire subcarrier frequency signals are equally divided into two regions. However, if the technical spirit of the circuit shown in FIG. 7 is expanded, the embodiments may be uniformly distinguished, and the embodiments may be divided into three or more regions. Of course it is possible.

In the above description, the technical idea of the present invention has been described with the accompanying drawings, which illustrate exemplary embodiments of the present invention by way of example and do not limit the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

110: modulator 120: data serial-to-parallel converter
130: quadrature frequency division modulation module 140: power amplifier
150: antenna

Claims (18)

A plurality of data input in parallel is divided into N groups (N is a natural number of 2 or more), and a plurality of data belonging to each group are orthogonal using a plurality of subcarrier signals and local oscillation signals having different frequency characteristics. N OFM blocks for frequency division modulation to generate N sub-RF signals; And
And a first adder for adding the N sub-RF signals to generate an RF signal. The method of claim 1, wherein the N ODF blocks,
Generating a first sub-RF signal by performing orthogonal frequency division modulation on 1/2 data among the plurality of data by using 1/2 subcarrier signals and the local oscillation signal among the plurality of subcarrier signals; 1 ODF block; And
And a second ODF block configured to generate a second sub-RF signal by performing orthogonal frequency division modulation on the remaining plurality of data using the remaining number of subcarrier signals and the local oscillation signal. The method of claim 2,
The first ODF block,
A plurality of first subcarrier frequency mixers for performing frequency mixing on a plurality of data using the plurality of subcarrier signals;
A second adder for summing frequency-mixed signals output from the plurality of frequency mixers; And
A first radio frequency mixer configured to generate the first sub-RF signal by frequency mixing a signal output from the second adder using the local oscillation signal,
The second ODF block,
A plurality of second subcarrier frequency mixers for performing frequency mixing on the remaining plurality of data using the remaining plurality of subcarrier signals;
A third adder for adding up the frequency mixed signals output from the plurality of frequency mixers; And
And a second radio frequency mixer configured to generate the second sub-RF signal by frequency mixing the signal output from the third adder using the local oscillation signal. The method of claim 3,
And the local oscillation signal having a higher frequency than the plurality of subcarriers. A first RF signal is generated by performing orthogonal frequency division modulation on 64 data among 128 data inputted in parallel using 64 subcarrier signals among 128 subcarrier signals and the local oscillation signal. Orthogonal frequency division modulation block;
A second orthogonal frequency division modulation block configured to generate a second RF signal by performing orthogonal frequency division modulation on the remaining 64 data using the remaining 64 subcarrier signals and the local oscillation signal; And
And a first adder for adding the first RF signal and the second RF signal to generate an RF signal. The method of claim 5,
The first orthogonal frequency division modulation block is,
64 first subcarrier frequency mixers which perform frequency mixing on the 64 data using the 64 subcarrier signals;
A second adder for generating a first IF signal by adding the 64 mixed signals output from the first subcarrier frequency mixers; And
And a first radio frequency mixer configured to generate the first RF signal by performing frequency mixing on the first IF signal using the local oscillation signal.
The second orthogonal frequency division modulation block,
64 second subcarrier frequency mixers which perform frequency mixing on the remaining 64 data using the remaining 64 subcarrier signals;
A third adder which adds 64 mixed signals output from the second subcarrier frequency mixers to generate a second IF signal; And
And a second radio frequency mixer configured to generate the second RF signal by performing frequency mixing on the second IF signal using the local oscillation signal. The method of claim 6,
And the local oscillation signal having a higher frequency than the plurality of subcarrier signals. In the ＵＷＢ transmitter which modulates and transmits the modulated transmission data by RF orthogonal frequency division modulation to the air,
A data serial-parallel converter for converting the modulated transmission data serially input into a plurality of parallel data;
An orthogonal frequency division modulation module for generating a transmission signal by performing orthogonal frequency division modulation on the plurality of parallel data; And
An antenna for propagating the transmission signal to the air,
The orthogonal frequency division modulation module,
Orthogonal frequency division modulation by dividing the plurality of parallel data into groups of N (N is a natural number of 2 or more) and using a plurality of subcarriers and local oscillation signals having different frequency characteristics. N ODF blocks to generate N sub-RF signals; And
And a first adder for adding the N sub-RF signals to generate the transmission signal. The method of claim 8, wherein the ODF block,
A first sub-RF signal is generated by performing orthogonal frequency division modulation on 1/2 data among the plurality of data using 1/2 subcarrier signals and a local oscillation signal among the plurality of subcarrier signals. ODF block; And
And a second OPM block for performing orthogonal frequency division modulation on the remaining plurality of data using the remaining number of subcarrier signals and the local oscillation signal to generate a second sub-RF signal. 10. The method of claim 9,
The first ODF block,
A plurality of first subcarrier frequency mixers for performing frequency mixing on a plurality of data using the plurality of subcarrier signals;
A second adder for summing frequency-mixed signals output from the plurality of frequency mixers; And
A first radio frequency mixer configured to generate the first sub-RF signal by frequency mixing a signal output from the second adder using the local oscillation signal,
The second ODF block,
A plurality of second subcarrier frequency mixers for performing frequency mixing on the remaining plurality of data using the remaining plurality of subcarrier signals and a local oscillation signal;
A third adder for adding up the frequency mixed signals output from the plurality of frequency mixers; And
And a second radio frequency mixer configured to generate the second sub-RF signal by frequency mixing the signal output from the third adder using the local oscillation signal. The method of claim 10,
The local oscillation signal having a higher frequency than the plurality of subcarrier signals. The method of claim 8,
And a modulator for modulating the transmission data to generate the modulated transmission data. The method of claim 8,
And a power amplifier for amplifying and transmitting a transmission signal output from the quadrature frequency division modulation module to the antenna. In the ＵＷＢ transmitter which modulates and transmits the modulated transmission data by RF orthogonal frequency division modulation to the air,
A data serial-to-parallel converter for converting the modulated transmission data input in series into 128 parallel data;
An orthogonal frequency division modulation module for generating a transmission signal by performing orthogonal frequency division modulation on the 128 parallel data; And
An antenna for propagating the transmission signal to the air,
The orthogonal frequency division modulation module,
A first RF signal is generated by performing orthogonal frequency division modulation on 64 data among the 128 data inputted in parallel using 64 subcarrier signals and a local oscillation signal among 128 subcarrier signals. Orthogonal frequency division modulation block;
A second orthogonal frequency division modulation block configured to generate orthogonal frequency division modulation on the remaining 64 data using the remaining 64 subcarrier signals and the local oscillation signal; And
And a first adder for adding the first RF signal and the second RF signal to generate the transmission signal. The method of claim 14,
The first orthogonal frequency division modulation block is,
64 first subcarrier frequency mixers each performing frequency mixing on the 64 data using the 64 subcarrier signals;
A second adder for generating a first IF signal by adding the 64 mixed signals output from the first subcarrier frequency mixers; And
And a first radio frequency mixer configured to generate the first RF signal by performing frequency mixing on the first IF signal using the local oscillation signal.
The second orthogonal frequency division modulation block,
64 second subcarrier frequency mixers which perform frequency mixing on the remaining 64 data using the remaining 64 subcarrier signals;
A third adder which adds 64 mixed signals output from the second subcarrier frequency mixers to generate a second IF signal; And
And a second radio frequency mixer configured to generate the second RF signal by performing frequency mixing on the second IF signal using the local oscillation signal. The method of claim 14,
The local oscillation signal having a higher frequency than the plurality of subcarrier signals. The method of claim 14,
And a modulator for modulating the transmission data to generate the modulated transmission data. The method of claim 14,
And a power amplifier for amplifying and transmitting a transmission signal output from the quadrature frequency division modulation module to the antenna.

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