KR101470592B1 - Data transmission apparatus and data transmission method for inserting of additional data at data modulation, and data reconstitution apparatus and data reconstitution method for separately processing data - Google Patents

Abstract

The present invention relates to a transmitting and receiving apparatus and method for transmitting data in addition to a CE-OFDM modulation scheme having characteristics that are robust against multipath fading and having a constant amplitude. The service channel information, the modulation parameter information of the physical layer, and the like can be transmitted by using the additional secured information channel. By using this information, it is possible to save the service search time and power of the receiver.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission apparatus and method capable of adding data when data is modulated and a data separation and recovery method and an apparatus and method for data separation and restoration,

The present invention relates to a data transmission apparatus and method having a data modulation function. More particularly, the present invention relates to a data transmitting apparatus and method capable of inserting added data at the time of data modulation. The present invention also relates to a data restoration apparatus and method having a data demodulating function. More particularly, the present invention relates to an apparatus and method for restoring data by separating and restoring data.

OFDM (Orthogonal Frequency Division Multiplexing) is a transmission method widely used in wireless communication since it has a simple equalizer and strong characteristics for multipath fading. OFDM is used in various wireless communication systems such as wireless local area network (WLAN), wireless metropolitan area network (WMAN), digital audio broadcasting (DAB), and digital video broadcasting (DVB).

However, the OFDM signal has a very high average power to peak power ratio (PAPR) at a transmission end. As the PAPR increases, the nonlinear distortion occurs due to the power amplifier (PA) of the transmitter, and the OFDM signal is very sensitive to the distortion. At this time, if sufficient backoff is not given to the power, the frequency spectrum of the communication system is widened, distortion due to inter-frequency modulation occurs, and consequently, the performance of the communication system is deteriorated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a data transmitting apparatus and method for additionally inserting data by using a characteristic having the largest energy to a DC component among CE-OFDM signal spectrum components .

It is another object of the present invention to provide a data restoring apparatus and method for separating further inserted data and demodulating the respective data.

According to an aspect of the present invention, there is provided an apparatus and method for performing a method of modulating a first input data by digitally modulating the first input data according to a multicarrier modulation scheme, A first data modulator for generating a first data signal; A second symbol mapping unit for mapping the added second input data after the first input data is input to generate a second mapping data; A second data modulator which combines the first modulation data with the second mapping data and again digitally modulates the first modulation data according to a predetermined modulation scheme to generate second modulation data; And a data transmitter for transmitting the second modulated data to the outside.

Preferably, the second data modulator adds the phase information of the symbols related to the second mapping data to the DC component of the signal containing the first modulation data when the second mapping data is combined with the first modulation data do.

Preferably, the second data modulator has a first combination for adding the phase value of the first modulated data and the phase value of the second mapped data when the second mapped data is combined with the first modulated data, And a third combination for subtracting a phase value of the first modulated data from a phase value of the second mapped data, and a third combination for subtracting a phase value of the first modulated data from a phase value of the second mapped data. .

Preferably, the second data modulator uses the modulation scheme different from the multicarrier modulation scheme by the predetermined modulation scheme.

Preferably, the second symbol mapping unit performs symbol mapping of the second input data by phase-modulating the second input data.

Advantageously, the data transmitting apparatus is implemented as a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) transmitter.

Preferably, the first data modulator includes: a parallel data converter for converting the first input data, which is input in a serial manner, into parallel data; The first symbol mapping unit generating first mapping data by symbol mapping the parallel data; And an inverse Fourier transformer for performing inverse Fourier transform on the first mapping data to generate the first modulated data.

According to another aspect of the present invention, there is provided a data modulation method, comprising: a first data modulation step of generating first modulation data by digitally modulating a first input data according to a multicarrier modulation method, the first data mapping step including a first symbol mapping step of mapping first input data; A second symbol mapping step of mapping the added second input data after the first input data is input to generate a second mapping data; A second data modulating step of combining the first modulated data with the second mapping data and digitally modulating the first modulated data according to a predetermined modulation scheme to generate second modulated data; And a data transmitting step of transmitting the second modulated data to the outside.

Preferably, the second data modulating step may include phase information of symbols related to the second mapping data to a DC component of a signal containing the first modulation data when the second mapping data is combined with the first modulation data, Add.

Preferably, the second data modulating step may include a first combination of adding a phase value of the first modulated data and a phase value of the second mapped data when the second mapped data is combined with the first modulated data, A second combination for subtracting a phase value of the second mapping data from a phase value of the first modulation data and a third combination for subtracting a phase value of the first modulation data from a phase value of the second mapping data, .

Preferably, the second data modulation step uses a modulation scheme different from the multicarrier modulation scheme by the predetermined modulation scheme.

Advantageously, the second symbol mapping step phase-modulates the second input data to perform symbol mapping of the second input data.

Preferably, the first data modulating step includes a parallel data converting step of converting the first input data, which is input in serial, into parallel data; The first symbol mapping step of generating first mapping data by symbol mapping the parallel data; And an inverse Fourier transform step of performing inverse Fourier transform on the first mapping data to generate the first modulated data.

According to another aspect of the present invention, the second data is extracted from the combined data obtained by combining the second data with the first data, the first data is first demodulated according to a predetermined first demodulation method, and the combined data, A data demodulator for performing digital demodulation later according to the determined second demodulation scheme; A second data decompression unit that demaps the digitally demodulated second data to recover the second data; And a first data decompression unit for digitally demodulating the digitally demodulated combined data again according to a multicarrier demodulation scheme to recover the first data.

Preferably, the data demodulator performs digital demodulation according to the first demodulation scheme based on phase information of symbols added to a DC component of a signal containing the combined data.

Preferably, the data demodulation unit demodulates the first combined data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted in performing the digital demodulation according to the second demodulation scheme, The second combination data obtained by adding the phase value of the data is used.

Preferably, the data demodulation unit uses a demodulation method different from the multicarrier demodulation method in the first demodulation method or the second demodulation method.

Preferably, the data separation and recovery apparatus is implemented as a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) receiver.

Preferably, the data separation and recovery apparatus further includes a data receiving unit operatively associated with the data transmitting apparatus that couples the second data to the first data when the second data is modulated, and receives the combined data from the data transmitting apparatus do. Preferably, the data transmission apparatus further includes a first symbol mapping unit for mapping the first data to a symbol, and the first data mapping unit may include a first symbol mapping unit for digitally modulating the first data according to a multicarrier modulation scheme to generate first modulation data, A data modulator; A second symbol mapping unit for generating second mapping data by symbol-mapping the added second data after the first data is input; A second data modulator which combines the first modulation data with the second mapping data and again digitally modulates the first modulation data according to a modulation scheme different from the multicarrier modulation scheme to generate the combined data; And a data transmission unit for transmitting the combined data to the data separation and recovery apparatus.

Preferably, the data separation and recovery apparatus further includes a parallel data conversion unit for converting the digitally demodulated combined data into parallel data when the serial data is input, wherein the first data decompression unit performs a Fourier transform on the parallel data, A Fourier transform unit for generating data; A symbol demapping unit for generating symbol demapping data by symbol demapping the Fourier transform data; And a serial data conversion unit for converting the symbol demapping data into serial data to recover the first data.

According to another aspect of the present invention, the second data is extracted from the combined data obtained by combining the second data with the first data, the first data is first demodulated according to a predetermined first demodulation method, and the combined data, A data demodulating step of performing digital demodulation after a predetermined second demodulation scheme; A second data restoring step of restoring the second data by demapping the digitally demodulated second data; And a first data restoring step of restoring the first data by digitally demodulating the digitally demodulated combined data again according to a multicarrier demodulation method.

Preferably, the data demodulating step performs digital demodulation according to the first demodulating method based on phase information of symbols added to a DC component of a signal containing the combined data, and the data demodulating step comprises: The first combined data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted, or the second combined data obtained by adding the phase values of the second data, .

Preferably, the data demodulating step uses a demodulation method different from the multicarrier demodulation method in the first demodulation method or the second demodulation method.

Preferably, the data separation / decompression method further comprises a data receiving step of interlocking with the data transmitting apparatus for combining the second data with the first data during the secondary data modulation, and receiving the combined data from the data transmitting apparatus .

Preferably, the data separation / decompression method further comprises a parallel data conversion step of converting the digitally demodulated combined data into parallel data when the serial data is input, wherein the first data reconstruction step performs a Fourier transform on the parallel data, A Fourier transform step of generating Fourier transform data; A symbol demapping step of generating symbol demapping data by symbol demapping the Fourier transform data; And a serial data conversion step of converting the symbol demapping data into serial data to restore the first data.

The present invention proposes a data transmission / reception apparatus for transmitting data in addition to the CE-OFDM modulation / demodulation scheme which satisfies OFDM characteristics robust against multipath fading and has a constant amplitude. According to the present invention, the following effects can be obtained. First, the service channel information, the modulation parameter information of the physical layer, and the like can be transmitted together using the additional secured information channel. Second, the service search time can be saved and the power of the transmitter / receiver can be reduced.

1 is a block diagram schematically showing a data transmitting apparatus according to a preferred embodiment of the present invention.
2 is a diagram illustrating an embodiment of a data transmitting apparatus according to the present embodiment.
3 is a reference diagram for explaining driving of a data transmitting apparatus according to an embodiment.
4 is a flowchart schematically illustrating a data transmission method according to a preferred embodiment of the present invention.
5 is a block diagram schematically illustrating a data restoration apparatus according to a preferred embodiment of the present invention.
6 is a detailed block diagram illustrating the internal configuration of the data transmitting apparatus and the data restoring apparatus according to the present embodiment.
7 is a diagram illustrating an embodiment of a data restoration apparatus according to the present embodiment.
8 is a flowchart schematically illustrating a data restoration method according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

1 is a block diagram schematically showing a data transmitting apparatus according to a preferred embodiment of the present invention. 6A is a block diagram showing in detail the internal structure of the data transmitting apparatus according to the present embodiment.

1, the data transmitting apparatus 100 is capable of adding data when data is modulated. The data transmitting apparatus 100 includes a first data modulator 110, a second symbol mapper 120, a second data modulator 130, A first power supply unit 140, a first power supply unit 150, and a first main control unit 160.

In this embodiment, the data transmission apparatus 100 may be implemented as a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) transmitter. Considering this point, the data transmitting apparatus 100 is defined as a transmitting apparatus that transmits information to a changed phase by changing the phase of the DC component by using a characteristic that has the largest amount of energy to the DC component among the CE-OFDM signal spectrum components can do. The data transmitting apparatus 100 can reduce the PAPR to 0 dB by using the CE-OFDM modulation scheme. This is because the CE-OFDM satisfies the OFDM property robust against multipath fading and has a constant amplitude characteristic.

The first data modulator 110 performs a function of digitally modulating the first input data according to a multicarrier modulation scheme to generate first modulated data. The first data modulator 110 uses OFDM (Orthogonal Frequency Division Multiplexing) modulation in a multicarrier modulation scheme.

The first data modulator 110 may include a parallel data converter 111, a first symbol mapper 112 and an inverse Fourier transformer 113 as shown in FIG. 6A. The parallel data conversion unit 111 performs a function of converting first input data input in serial into parallel data. The first symbol mapping unit 112 performs symbol mapping on the first input data. More specifically, the first symbol mapping unit 112 performs symbol mapping of parallel data to generate first mapping data. The inverse Fourier transformer 113 performs inverse Fourier transform on the first mapping data to generate first modulated data.

The second symbol mapping unit 120 performs a function of generating second mapping data by symbol-mapping the added second input data after inputting the first input data. The second input data is input after the first input data is input to the data transmission apparatus 100. [ The second input data includes service channel information, modulation parameter information of the physical layer, and the like.

The second symbol mapping unit 120 performs symbol mapping of the second input data by phase-modulating the second input data. The first symbol mapping unit 112 may use a QPSK scheme, a 16QAM scheme, a 64QAM scheme, or the like in symbol mapping of the first input data. At this time, the first symbol mapping unit 112 can perform symbol mapping on the first input data mainly using the amplitude modulation method. On the other hand, the second symbol mapping unit 120 may use a BPSK scheme, a DBPSK scheme, a QPSK scheme, a DQPSK scheme, an 8PSK scheme, or the like in symbol mapping of the second input data. The second symbol mapping unit may map the second input data to symbols using only the phase modulation method. However, the present invention is not necessarily limited to this embodiment.

The second data modulator 130 combines the first modulation data with the second mapping data, and performs a function of generating the second modulation data by performing a digital modulation again according to a predetermined modulation scheme. In this embodiment, the second data modulation unit 130 uses a modulation scheme different from the multicarrier modulation scheme by a predetermined modulation scheme. Preferably, the second data modulator 130 uses angle modulation in a modulation scheme different from the multicarrier modulation scheme, and it is also possible to use phase modulation, amplitude modulation, modulation combining phase and amplitude, and the like Do.

Digital modulation is divided into four major categories: multilevel modulation, narrowband modulation, multicarrier modulation, and spread spectrum modulation. The multilevel modulation includes a phase shift keying (PSK) which is a phase modulation, a pulse amplitude modulation (PAM) which is an amplitude modulation, a quadrature amplitude modulation (QAM) which is a combination of a phase and an amplitude, and a residual side band (VSB) modulation. Narrowband modulation includes π / 4 quadrature phase shift keying (QPSK), which limits the PSK band, and Gaussian filter minimum shift keying (GMSK), which limits the band of the minimum shift keying (MSK). In the multicarrier modulation scheme, data is divided into several hundreds of carriers and multiplexed, and orthogonal frequency division multiplexing (OFDM) is a representative example. The spread spectrum modulation scheme is classified into direct spreading (SS-DS) and frequency hopping (SS-FH). Considering the kind of digital modulation, multicarrier modulation and other modulation schemes can also be defined by multilevel modulation, narrowband modulation, and spread spectrum modulation.

The second data modulator 130 adds the phase information of the symbols associated with the second mapping data to the DC component of the signal containing the first modulation data when the second mapping data is combined with the first modulation data.

The second data modulator 130 may include a first combination for adding the phase value of the first modulated data and the phase value of the second mapped data when the second mapped data is combined with the first modulated data, And a third combination that subtracts the phase value of the first modulated data from the phase value of the second mapped data.

The data transmission unit 140 transmits the second modulated data to the outside. Preferably, the data transmitting unit 140 transmits the second modulated data in the direction of the object. If the data transmitting apparatus 100 is a CE-OFDM transmitter, the object may be a CE-OFDM receiver.

The first power supply unit 150 performs a function of supplying power to the units constituting the data transmission apparatus 100.

The first main control unit 160 performs a function of controlling the overall operation of each unit constituting the data transmission apparatus 100.

The data transmitting apparatus 100 is a transmitting apparatus capable of further inserting data in a transmission scheme in which OFDM modulation and each modulation are combined. Hereinafter, the data transmitting apparatus 100 will be described with reference to an embodiment. 2 is a diagram illustrating an embodiment of a data transmitting apparatus according to the present embodiment. 3 is a reference diagram for explaining driving of a data transmitting apparatus according to an embodiment.

The CE-OFDM transmitter 200 of FIG. 2 is an embodiment of the data transmitting apparatus 100 of FIG. 1, and is a transmitter capable of lowering the PAPR to 0 dB through the combination of the OFDM modulation scheme and each modulation scheme. In the present embodiment, a modulation scheme combining an OFDM modulation scheme and each modulation scheme is defined as CE-OFDM (Constant Envelope Orthogonal Frequency Division Multiplexing). CE-OFDM satisfies OFDM characteristics robust to multi-path fading and has a constant amplitude. In addition, CE-OFDM is characterized in that the DC component has the highest energy among the signal spectrum components. It is an object of the present invention to transmit additional information to the phase of the DC component by using the point where energy is concentrated on the DC component. Therefore, the CE-OFDM transmitter 200, which will be described below, can be defined as a transmitting apparatus that transmits information to a changed phase by changing the phase of a DC component in the CE-OFDM scheme.

The input data is data in the form of an input bit, which is stored in an input signal for CE-OFDM. When the input data is input as a serial, the S / P block 230 converts the serial data into parallel data. The S / P block 230 is for S / P (Serial-to-Parallel) conversion and has a configuration that functions as a parallel data conversion unit 111 of FIG. 6A. The first symbol mapper 240 generates symbol data from parallel data using a QPSK scheme, a 16QAM scheme, a 64QAM scheme, or the like. The first symbol mapper 240 is configured to function as the first symbol mapping unit 112 of FIG. 6 (a). The IFFT block 250 performs IFFT transform to transmit the OFDM signal on the time axis. The IFFT block 250 is configured to function as the inverse Fourier transformer 113 of FIG. 6 (a). 2, the S / P block 230, the first symbol mapper 240, and the IFFT block 250 constitute the OFDM modulator 210. The OFDM modulator 210 at this time is configured to function as the first data modulator 110 of FIG. An Angle Modulation & Phase Modulation block 260 functions to modulate each IFFT-converted signal. Each modulation and phase modulation block 260 is a configuration that functions as the second data modulation unit 130 in FIG.

이며, 45도 위상을 갖는다. 이후, 각 변조 & 위상 변조 블록(260)에서는 DC 성분에 맵핑된 심볼의 위상 정보를 추가하여 각 변조 신호(즉, IFFT 변환된 신호를 각 변조한 것)와 결합하여 전송한다.New input data to be newly added is symbol-mapped to BPSK, DBPSK, QPSK, DQPSK, and 8PSK in the second symbol mapper 220. The second symbol mapper 220 is configured to function as the second symbol mapping unit 120 of FIG. The second symbol mapper 220 to which data is to be transmitted further uses various types of phase modulation such as BPSK, DBPSK, QPSK, DQPSK, and 8PSK. For example, if the second symbol mapper 220 is an 8PSK symbol mapper, it can be expressed as shown in FIG. 3 (a). 3 (a), assuming that the input information bit is 001, the signal through the second symbol mapper 220 is

And has a 45-degree phase. Then, each modulation and phase modulation block 260 adds the phase information of the symbol mapped to the DC component and combines the modulated signal with each modulated signal (that is, each modulated IFFT-transformed signal) and transmits it.

Each modulation & phase modulation block 260 modulates the IFFT output signal of OFDM. That is, if the IFFT output signal is X ₁ , X ₂ , ... , X _n , the modulated signal θ (k) of the k-th IFFT signal is given by Equation 1 below. Where n is the IFFT size.

The spectrum of each modulated signal of the IFFT signal is as shown in FIG. 3 (b), and the DC component has a high energy. At this time, the modulated signals θ (1), θ (2), θ (3), ..., θ (n) are added or subtracted to the phase θ new of the newly generated symbol mapper. That is, (1) θ (new) + [θ (1), θ (2), θ , θ (n)], 2 θ (new) - [θ (1), θ (2), θ (3) , θ (n)], ③ [θ (1), θ (2), θ (3), ... , θ (n)] + θ (new), 4 [θ (1), θ (2), θ ,? (n)] -? (new). The data transfer unit selects one of these four cases and transmits the selected one. (new) is generated for each OFDM symbol, and the phase of the DC component for each OFDM symbol is changed by? (new).

Next, a data transmission method of the data transmission apparatus 100 will be described. 4 is a flowchart schematically illustrating a data transmission method according to a preferred embodiment of the present invention.

First, the first input data is digitally modulated according to a multicarrier modulation method to generate first modulated data (a first data modulating step, S400). The first data modulation step (S400) may include a parallel data conversion step, a first symbol mapping step, and an inverse Fourier transform step. In the parallel data conversion step, the first input data inputted in serial is converted into parallel data. In the first symbol mapping step, the first input data is symbol-mapped, and more specifically, the first mapping data is generated by symbol-mapping the parallel data. In the inverse Fourier transform step, the first mapping data is subjected to inverse Fourier transform to generate first modulated data.

After the first data modulation step S400, the second input data is input and then the added second input data is symbol-mapped to generate second mapping data (second symbol mapping step S410). The second symbol mapping step S410 performs symbol mapping of the second input data by phase-modulating the second input data.

After the second symbol mapping step (S410), the second modulation data is generated by combining the second mapping data with the first modulation data and performing digital modulation again according to a predetermined modulation method (second data modulation step, S420). In the second data modulation step (S420), a modulation scheme different from the multicarrier modulation scheme is used, and preferably each modulation scheme is used. The second data modulation step S420 adds the phase information of the symbols associated with the second mapping data to the DC component of the signal containing the first modulation data when combining the second mapping data with the first modulation data. The second data modulation step S420 includes a first combination of adding a phase value of the first modulated data and a phase value of the second mapped data when the second mapped data is combined with the first modulated data, And a third combination that subtracts the phase value of the first modulated data from the phase value of the second mapped data.

After the second data modulation step (S420), the second modulation data is transmitted to the outside (data transmission step, S430).

Next, an apparatus for restoring data will be described. 5 is a block diagram schematically illustrating a data restoration apparatus according to a preferred embodiment of the present invention. 6 (b) and 6 (c) are block diagrams showing in detail the internal structure of the data restoration apparatus according to the present embodiment.

5, the data decompression apparatus 500 includes a data demodulation unit 510, a second data decompression unit 520, a first data decompression unit 530, a second power source unit 540, and a second main control unit 550 ). The data restoring apparatus 500 is a device for separating and restoring data. The data restoration apparatus 500 may be interlocked with the data transmission apparatus 100 of FIG. 1. In this case, the data restoration apparatus 500 may be implemented as a CE-OFDM receiver.

The data demodulation unit 510 extracts second data from the combined data obtained by combining the second data with the first data, digitally demodulates the first data according to a predetermined first demodulation scheme, and outputs the combined data, Performs a digital demodulation function according to a second demodulation method. Assuming that the data restoring apparatus 500 receives the signal transmitted by the data transmitting apparatus 100 of FIG. 1, the first data means that the first input data of FIG. 1 is modulated, and the second data Means that the second input data of Fig. 1 is modulated.

The data demodulator 510 uses a demodulation scheme different from the multicarrier demodulation scheme in the first demodulation scheme or the second demodulation scheme. The first demodulation scheme and the second demodulation scheme may be the same or different from each other. In this embodiment, phase demodulation is used as a first demodulation method and angle demodulation is used as a second demodulation method. In this embodiment, Orthogonal Frequency Division Multiplexing (OFDM) demodulation is used in a multicarrier demodulation scheme. It is also possible to use phase demodulation, amplitude demodulation, demodulation combining phase and amplitude, and the like as the demodulation system other than the multicarrier demodulation system.

The data demodulator 510 performs digital demodulation according to the first demodulation scheme based on the phase information of the symbols added to the DC component of the signal containing the combined data.

The data demodulator 510 adds the first combined data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted during the digital demodulation according to the second demodulation scheme, And uses the second combined data obtained later. If the combined data is the combined data obtained by adding the phase value of the first data and the phase value of the second data or the combined data obtained by subtracting the phase value of the first data from the phase value of the second data, Uses the first combined data in performing the digital demodulation according to the second demodulation scheme. On the other hand, if the combined data is the combined data obtained by subtracting the phase value of the second data from the phase value of the first data, the data demodulator 510 uses the second combined data in performing the digital demodulation according to the second demodulation method.

The second data decompression unit 520 performs a function of demapping the digitally demodulated second data to recover the second data. The second data restoring unit 520 restores the second data to original data. That is, the second data decompression unit 520 restores the second data to that before the data modulation.

The first data decompression unit 530 performs digital demodulation of the digitally demodulated combined data according to a multicarrier demodulation method to recover the first data. The first data restoring unit 530 restores the first data into the circular data.

The second power supply unit 540 supplies power to each unit constituting the data recovery apparatus 500.

The second main control unit 550 controls the overall operation of each unit constituting the data restoration apparatus 500.

The data restoring apparatus 500 may further include a data receiving unit 560 as shown in FIG. 6 (b). The data receiving unit 560 may be interlocked with a data transmitting apparatus (ex. 100 in FIG. 1) coupling the first data with the second data during the secondary data modulation, and at this time, . When the data transmitting apparatus is implemented with reference numeral 100 in FIG. 1, the data transmitting apparatus includes a first data modulating unit, a second symbol mapping unit, a second data modulating unit, and a data transmitting unit. The first data modulator includes a first symbol mapping unit for symbol-mapping first data, and generates first modulation data by digitally modulating the first data according to a multicarrier modulation scheme. The second symbol mapping unit generates second mapping data by symbol-mapping the added second data after inputting the first data. The second data modulator combines the second modulation data with the first modulation data and generates the combined data by again modulating the second mapping data according to the modulation scheme (ex. Modulation) different from the multicarrier modulation scheme. The data transmission unit transmits the combined data to the data recovery apparatus 500.

The data restoring apparatus 500 may further include a parallel data converting unit 570 as shown in FIG. 6 (b). The parallel data converter 570 converts the digital demodulated combined data into parallel data when the serial data is input. The first data decompression unit 530 may include a Fourier transform unit 531, a symbol demapping unit 532, and a serial data conversion unit 533 as shown in FIG. 6C. The Fourier transform unit 531 performs Fourier transform on the parallel data to generate Fourier transform data. The symbol demapping unit 532 demaps the Fourier transform data to generate symbol demapping data. The serial data conversion unit 533 converts the symbol demapping data into serial data to restore the first data.

Next, the data restoration apparatus 600 will be described with reference to an embodiment. 7 is a diagram illustrating an embodiment of a data restoration apparatus according to the present embodiment. FIG. 7 is an example of a case where the data restoration apparatus 600 is implemented by the CE-OFDM receiver 700. FIG.

The received CE-OFDM signal demodulates the phase information of the DC component in the phase demodulation & angle demodulation block 710. Thereafter, the phase demodulation & demodulation block 710 demodulates the CE-OFDM signal. The phase demodulation & demodulation block 710 is a configuration that functions as the data demodulation unit 510 of FIG.

이 되고, DC 성분의 위상은 45도가 되며, 변화된 위상 45도의 값은 001로 복조를 하면 된다. 각 복조(Angle demodulation)을 위해 수신된 신호에 DC 성분의 변화된 위상을 빼거나 더하여 각 복조를 수행하면 된다. 예를 들어, 송신된 신호가 θ(new)+[θ(1), θ(2), θ(3), …, θ(n]이면 수신된 신호에서 DC 성분의 변화된 위상 즉, θ(new)를 뺀 후 각 복조를 수행한다. 위의 가정에서는 θ(new)는 45도이다.Phase demodulation & demodulation block 710 obtains the phase of the DC component in the received signal and performs phase demodulation. For example, assuming that the transmission side modulates the 001 information bits to 8PSK, the DC component of the received signal, that is, the average value of the received signal

The phase of the DC component becomes 45 degrees, and the value of the changed phase of 45 degrees is demodulated to 001. [ It is sufficient to subtract or add the changed phase of the DC component to the received signal for each demodulation to perform each demodulation. For example, if the transmitted signal is θ (new) + [θ (1), θ (2), θ (3), ... , and θ (n), the demodulation is performed after subtracting the changed phase of the DC component, ie, θ (new), from the received signal.

When the phase information of the DC component is demodulated in the phase demodulation and angle demodulation block 710, the first symbol demapper 770 demaps the signal. And then restores the new data information bits. The first symbol demapper 770 is configured to function as the second data decompression unit 520 of FIG. 5, and uses BPSK, QPSK, 8PSK, and the like in demapping.

After demodulating the CE-OFDM signal in the phase demodulation & demodulation block 710, the signal is demodulated in the frequency domain through an FFT transformer 740 via a serial-to-parallel (S / P) block 720, . The FFT output signal then restores the CE-OFDM information bits through the second symbol demapper 750 and the Parallel-to-Serial (P / S) block 760. The S / P block 720 converts the input signal into a serial-to-parallel signal to perform FFT on each demodulated signal. The S / P block 720 is configured to function as the parallel data conversion unit 570 in FIG. 6 (b). The FFT transformer 740 transforms the frequency domain into a frequency domain, and functions as a Fourier transformer 531 of FIG. 6 (c). The second symbol demapper 750 reconstructs a transmission symbol through symbol demapping, and is a configuration that functions as a symbol demapping unit 532 in FIG. 6 (c). The second symbol demapper 750 uses QPSK, 16QAM, and the like when demapping. The P / S block 760 restores the information bits by parallel-to-serial, and has a configuration that functions as the serial data conversion unit 533 of FIG. 6 (c). The FFT transformer 740, the second symbol demapper 750, and the P / S block 760 may be combined to form an OFDM demodulator 730. The OFDM demodulator 730 is configured to function as the first data reconstructing unit 530 in FIG.

Next, a data restoring method of the data restoring apparatus 500 will be described. 8 is a flowchart schematically illustrating a data restoration method according to a preferred embodiment of the present invention.

First, the second data is extracted from the combined data obtained by combining the second data with the first data, and the digital data is first demodulated according to a predetermined first demodulation method, and the combined data from which the second data is extracted is subjected to a predetermined second demodulation method Followed by digital demodulation (data demodulation step, S800).

The data demodulation step S800 uses a demodulation system different from the multicarrier demodulation system in the first demodulation system or the second demodulation system.

The data demodulation step S800 performs digital demodulation according to the first demodulation scheme based on the phase information of the symbols added to the DC component of the signal containing the combined data. Alternatively, the data demodulating step (S800) may include first combining data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted during the digital demodulation according to the second demodulation scheme, And then uses the second combination data obtained.

After the data demodulation step (S800), the digital demodulated second data is symbol-demapped to restore the second data (second data restoring step, S810).

After the second data restoring step S810, the digital demodulated combined data is digitally demodulated again according to the multicarrier demodulation method to restore the first data (step S820). In this embodiment, the first data restoring step S820 may be performed simultaneously with the second data restoring step S810.

In the present embodiment, the data receiving step may be further performed before the data demodulating step S800. The data receiving step is interlocked with a data transmitting apparatus that couples the second data to the first data during the secondary data modulation, and receives the coupling data from the data transmitting apparatus.

Meanwhile, in the present embodiment, a parallel data conversion step may be further performed between the data demodulating step S800 and the first data restoring step S820. In the parallel data conversion step, the digitally demodulated combined data is converted into parallel data when it is inputted as a serial. In this case, the first data restoration step S820 may include a Fourier transform step, a symbol demapping step, and a serial data transform step. In the Fourier transform step, the parallel data is Fourier transformed to generate Fourier transform data. In the symbol demapping step, the symbol demapping data is generated by symbol demapping the Fourier transform data. In the serial data conversion step, the symbol demapping data is converted into serial data to restore the first data.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

The present invention relates to an apparatus and method relating to insertion of additional data in a transmission scheme combining OFDM modulation and angular modulation, and is applicable to a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) transmitter and a CE-OFDM receiver.

100: Data transmitting apparatus 110: First data modulating section
120: second symbol mapping unit 130: second data modulation unit
140: Data transmitter 200: CE-OFDM transmitter
210: OFDM modulator 220: second symbol mapper
230: S / P block 240: first symbol mapper
250: IFFT block 260: Each modulation and phase modulation block
500: Data restoration apparatus 510: Data demodulation unit
520: second data restoring unit 530: first data restoring unit
560: Data receiving unit 700: CE-OFDM receiver
710: Phase demodulation & demodulation block 720: S / P block
730: OFDM demodulator 740: FFT converter
750: second signal demapper 760: P / S block
770: first signal demapper

Claims (20)

A first data modulator including a first symbol mapper for symbol-mapping first input data, the first data modulator generating a first modulated data by digitally modulating the first input data according to a multicarrier modulation scheme;
A second symbol mapping unit for mapping the added second input data after the first input data is input to generate a second mapping data;
Wherein the first modulation data is generated by combining the first modulation data with the second mapping data and digitally modulating the second modulation data again according to a predetermined modulation scheme and when combining the second mapping data with the first modulation data, A second data modulator for adding phase information of symbols related to the second mapping data to a DC component of a signal containing modulation data; And
A data transmission unit for transmitting the second modulated data to the outside,
Wherein the data modulating means adds the data to the data. delete The method according to claim 1,
Wherein the second data modulator has a first combination for adding the phase value of the first modulated data and the phase value of the second mapped data when the second mapped data is combined with the first modulated data, A second combination of subtracting a phase value of the second mapping data from a phase value and a third combination of subtracting a phase value of the first modulation data from a phase value of the second mapping data, And data can be added when data modulation is performed. The method according to claim 1,
Wherein the second data modulator uses a modulation scheme different from the multicarrier modulation scheme by the predetermined modulation scheme. The method according to claim 1,
Wherein the second symbol mapping unit phase-modulates the second input data and performs symbol mapping of the second input data. The method according to claim 1,
Wherein the data transmission apparatus is implemented by a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) transmitter. A first data modulation step of generating first modulation data by digitally modulating the first input data according to a multicarrier modulation method, comprising: a first symbol mapping step of mapping first input data to symbols;
A second symbol mapping step of mapping the added second input data after the first input data is input to generate a second mapping data;
Wherein the first modulation data is generated by combining the first modulation data with the second mapping data and digitally modulating the second modulation data again according to a predetermined modulation scheme and when combining the second mapping data with the first modulation data, A second data modulation step of adding phase information of symbols related to the second mapping data to a DC component of a signal containing modulation data; And
A data transmission step of transmitting the second modulated data to the outside
Wherein the data is modulated by the data modulation method. delete 8. The method of claim 7,
The second data modulating step may include a first combination of adding a phase value of the first modulated data and a phase value of the second mapped data when the second mapped data is combined with the first modulated data, And a third combination for subtracting a phase value of the first modulated data from a phase value of the second mapped data is used as a combination of the first combination data and the second combination data, The data can be added when data modulation is performed. A first demodulating unit that first extracts the second data from the combined data obtained by combining the first data with the second data, digitally demodulates the first data according to a predetermined first demodulation scheme, and outputs the combined data, A data demodulator for performing digital demodulation according to the first demodulation scheme based on phase information of symbols added to a DC component of a signal containing the combined data;
A second data decompression unit that demaps the digitally demodulated second data to recover the second data; And
A first data decompression unit that digitally demodulates the digitally demodulated combined data according to a multicarrier demodulation scheme to recover the first data,
And a data restoring unit for restoring the data. delete 11. The method of claim 10,
Wherein the data demodulation unit demultiplexes the first combined data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted during the digital demodulation according to the second demodulation scheme, And the second combined data obtained by adding the second combined data. 11. The method of claim 10,
Wherein the data demodulation unit uses a demodulation scheme different from the multicarrier demodulation scheme in the first demodulation scheme or the second demodulation scheme. 11. The method of claim 10,
Wherein the data separation and recovery apparatus is implemented as a Constant Envelope (CE) -OFDM (Orthogonal Frequency Division Multiplexing) receiver. 11. The method of claim 10,
A data receiving unit coupled to the data transmitting apparatus for combining the second data with the first data when the second data is modulated,
Further comprising: a data decompressor for decompressing the data. 16. The method of claim 15,
The data transmitting apparatus includes:
A first data modulator for generating first modulation data by digitally modulating the first data according to a multicarrier modulation scheme, the first data modulator including a first symbol mapping unit for symbol-mapping the first data;
A second symbol mapping unit for generating second mapping data by symbol-mapping the added second data after the first data is input;
A second data modulator which combines the first modulation data with the second mapping data and again digitally modulates the first modulation data according to a modulation scheme different from the multicarrier modulation scheme to generate the combined data; And
And a data transmission unit for transmitting the combined data to the data separation / recovery unit
And a data restoring unit for restoring the data. A first demodulating unit that first extracts the second data from the combined data obtained by combining the first data with the second data, digitally demodulates the first data according to a predetermined first demodulation scheme, and outputs the combined data, And performing digital demodulation according to the first demodulation scheme based on phase information of symbols added to a DC component of a signal containing the combined data;
A second data restoring step of restoring the second data by demapping the digitally demodulated second data; And
A first data restoring step of restoring the first data by digitally demodulating the digitally demodulated combined data again according to a multicarrier demodulating method,
The method of claim 1, 18. The method of claim 17,
Wherein the data demodulating step includes demodulating the first combined data obtained by subtracting the phase value of the second data from the combined data from which the second data is extracted during the digital demodulation according to the second demodulation scheme, And the second combined data obtained after adding the value of the second combined data is used. 18. The method of claim 17,
Wherein the data demodulating step uses a demodulation scheme different from the multicarrier demodulation scheme according to the first demodulation scheme or the second demodulation scheme. 18. The method of claim 17,
A data receiving step of receiving the combined data from the data transmitting apparatus, the data receiving step being interlocked with a data transmitting apparatus for combining the first data with the second data upon secondary data modulation;
The method of claim 1, further comprising:

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