JP2008124644A - Interference avoiding transmission system, and method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an interference avoiding transmission system and a method thereof. <P>SOLUTION: An interference avoiding transmission system mainly comprises a transmitting apparatus and a receiving apparatus. In the transmission system, first data are received by an interference processing module included in the transmitting apparatus, a plurality of extended data are added to the first data to generate second data, zero data are substituted for a plurality of data in a data interference frequency band to generate transmission data, and then the transmission data are converted into a radio frequency signal and the radio frequency signal is transmitted to the receiving apparatus by a transmission processing module, so that a frequency band overlapped area can be avoided and mutual interference can be avoided. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a type of transmission system, and more particularly to a type of interference avoidance transmission system and method.

  As current science and technology continue to evolve, science and technology products are developing new products one after another. In particular, it is reflected in wireless products such as mobile phones and Bluetooth earphones. In order to avoid the influence on the communication quality due to mutual interference, a standard regarding a wireless network is promulgated by the Institute of Electrical Engineers (IEEE) and the Institute of Electrical Engineers (IEEE).

  In addition, the United States Federal Communications Commission (FCC) has established a kind of frequency band mask as a commercial purpose of this ultra-wideband technology, with the first report on ultra-wide band and the announcement of command technology, Protects ultra-wideband signals from interfering with other agreement bands. As an example, a global satellite positioning system (GPS) detector and a WiMAX (Worldwide Interoperability for Microwave Access) agreement assign a large continuous band to this frequency band mask. Among them, the transmission level (−41.25 dB / MHz) of the effective isotropic radiated power (EIRP) of the ultra-wideband uses the ultra-wideband communication technology of 3.1 GHz to 10.6 GHz.

The frequency band specified by the WiMAX agreement uses 3.6 GHz. Therefore, the WiMAX agreement and the ultra-wideband frequency band overlap, and the problem of mutual interference remains. For this reason, TI provides ECC / TG3TG3 # 10_XX, “UWB Interference Mitigation”, 10 ^th ECC / TG3 meeting, Compenhagen, July 2005 to provide a kind of automatic interference cancellation (Active Interference Cancel) Plan. The efficiency of the notch filter of the interference avoidance technology of TI is around 30 dB, and further, the processing capability of the interference avoidance technology of the ultra-wideband system is added around 40 dB, the processing of the interference avoidance technology presented in the paper of TI The total capacity reaches a level of 70 dB. However, the situation is still likely to interfere.

  In view of the above problems, the present inventor provides a kind of novel interference avoidance transmission system and method. The present plan solves the above-mentioned problems by eliminating the drawbacks of mutual signal interference caused by frequency band duplication.

  It is an object of the present invention to provide a kind of interference avoidance transmission system and method for processing a frequency overlap band by an interference processing module to avoid mutual interference of signals.

  It is an object of the present invention to provide a kind of interference avoidance transmission system and method, in which extension data is added by an additional unit and combined with a multiplexing device to avoid mutual interference due to frequency band duplication. .

  The interference avoidance transmission system of the present invention comprises a transmitting device and a receiving device. The transmission device includes a first reverse fast Fourier transform unit, an interference processing module, and a transmission processing module. The receiving device includes a reception processing module, a deletion unit, and a fast Fourier transform unit. The transmission method of the present invention receives input data from the first inverse Fourier transform unit and converts the input data into first data. When the first data is received by the interference processing module, a plurality of extension data is added to the first data, a second data is generated, a plurality of data in the interference band of the data is replaced with zero data, and the transmission data Is generated. The transmission processing module replaces the transmission data with a radio frequency signal and transmits the radio frequency signal.

  Subsequently, the receiving device receives the radio frequency signal from the processing module, converts the radio frequency signal into received data, deletes the extended data of the received data by the deleting unit, and reduces the reduced data by the fast Fourier transform unit. Generate and convert the reduction data to generate output data.

The invention of claim 1 is a transmission device comprising the following components,
A first inverse fast Fourier transform unit that receives input data and converts the input data into first data;
The interference processing module receives the first data, adds a plurality of extension data to the first data, generates second data, replaces the plurality of data in the interference frequency band of the data with zero data, Generate and
The transmission processing module converts the transmission data into a radio frequency signal, transmits the radio frequency signal,
A receiving device comprising the following components,
Receiving the radio frequency signal by a reception processing module, converting the radio frequency signal into received data;
Deleting the extension data prepared for the received data by a deletion unit, generating return data;
An interference avoidance transmission system is characterized in that the reduced data is converted and output data is generated by a first fast Fourier transform unit.
In the invention of claim 2, the interference processing module further comprises the following components:
An extension unit adds the extension data to the first data to generate second data,
A second Fast Fourier Transform unit that transforms the second data to generate third data;
The selection unit replaces a plurality of data in the interference frequency band of the third data with zero data to generate fourth data,
The interference avoidance transmission system according to claim 1, wherein the fourth data is converted into transmission data by a second reverse fast Fourier transform unit.
The invention according to claim 3 is the kind of interference avoidance transmission system according to claim 2, wherein the selection unit is a multiplexing device.
The invention according to claim 4 is the interference avoidance transmission system according to claim 1, wherein the extension data is a plurality of zero data.
In the invention of claim 5, the transmission processing module converts the transmission data into analog transmission data by a digital-analog converter,
2. The interference avoidance transmission system according to claim 1, wherein the analog transmission data is converted into the radio frequency signal by a radio frequency signal transmitter, and the radio frequency signal is transmitted by a transmitting antenna.
6. The interference avoidance transmission system according to claim 5, wherein the transmission processing module removes noise of the transmission data by a filter and transmits the transmission data to the digital-analog converter. It is said.
The invention according to claim 7 provides the interference avoidance transmission system according to claim 6, wherein the filter is a square root raised cosine filter.
The invention of claim 8 is characterized in that the transmitting device converts the serial input data into parallel input data by a serial parallel converter and transmits the parallel input data to the inverse Fourier transform unit. 1 is an interference avoidance transmission system.
The invention according to claim 9 is characterized in that the transmitting device converts the parallel transmission data into serial transmission data by a parallel-serial converter and transmits the serial transmission data to the transmission processing module. It is an interference avoidance transmission system.
In the invention of claim 10, the reception processing module receives the radio frequency signal by a transmission antenna,
A radio frequency signal receiver converts the radio frequency signal into the received data,
2. The interference avoidance transmission system according to claim 1, wherein the analog reception data is converted into digital reception data by an analog-digital converter.
The invention according to claim 11 is the interference avoidance transmission system according to claim 10, wherein the reception processing module removes noise of the received data by a filter and transmits the noise to the removal unit.
The invention of claim 12 is the interference avoidance transmission system according to claim 11, wherein the filter is a square root raised cosine filter.
The invention according to claim 13 is the interference according to claim 1, wherein the receiving device converts the serial transmission data into parallel transmission data by a serial parallel converter and transmits the parallel transmission data to the removal unit. It is an avoidance transmission system.
14. The interference avoidance transmission system according to claim 1, wherein the receiving device converts the output data by a parallel-serial converter and outputs the output data as serial output data. It is said.
The invention according to claim 15 provides the interference avoidance transmission system according to claim 1, wherein the receiving apparatus equalizes the output data by an equalizer.
The invention according to claim 16 provides the interference avoidance transmission system according to claim 1, wherein the receiving apparatus decodes the output data by a decoding unit.
The invention according to claim 17 is an interference avoidance transmission system according to claim 1, which can be applied to ultra-wideband orthogonal frequency division multiplexing.
The invention of claim 18 receives input data, converts the input data into first data,
Receiving the first data, adding a plurality of extension data to the first data, generating second data, replacing the plurality of data in the interference frequency band of the data with zero data, generating transmission data;
Converting the transmission data into a radio frequency signal, transmitting the radio frequency signal,
Receiving the radio frequency signal, converting the radio frequency signal into received data;
Deleting the extension data included in the received data to generate return data;
The reduction data is converted to generate output data, which is an interference avoidance transmission system method.
The invention of claim 19 receives the first data, adds a plurality of extension data to the first data, generates second data, replaces the plurality of data in the interference frequency band with zero data, and transmits the transmission data. The method further includes the following steps:
Adding the extension data to the first data to generate second data;
Converting the second data to generate third data;
The selection unit replaces a plurality of data in the interference frequency band of the third data with zero data to generate fourth data,
19. The interference avoidance transmission system method according to claim 18, wherein the fourth data is converted into the transmission data.
The invention of claim 20 is characterized in that a plurality of data in the interference frequency band of the third data is replaced with zero data, and the procedure for generating the fourth data uses a multiplexing method. The transmission system method.
The invention according to claim 21 is the method of the interference avoidance transmission system according to claim 18, wherein the extension data is a plurality of zero data.
The invention of claim 22 further includes the following steps in the procedure of converting the data of the transmission data into a radio frequency signal and transmitting the radio frequency signal.
The transmission data is converted into analog transmission data,
Converting the analog transmission data into the radio frequency signal;
19. The interference avoidance transmission system method according to claim 18, wherein the radio frequency signal is transmitted.
According to a twenty-third aspect of the present invention, there is provided the interference avoidance transmission system method according to the twenty-second aspect, further comprising: inspecting the transmission data and converting the transmission data.
The invention of claim 24 is the interference avoidance transmission system method according to claim 23, characterized in that the inspection method is based on a square root cosine method.
The invention of claim 25 further includes the following steps:
19. The interference avoidance transmission system method according to claim 18, wherein serial input data is replaced with parallel input data, and the input data is converted into first data.
The invention of claim 26 further includes the following procedure:
19. The interference avoidance transmission system method according to claim 18, wherein the parallel transmission data is converted into serial transmission data, and the transmission data is converted into a radio frequency signal.
In the invention of claim 27, the procedure for converting the radio frequency signal into received data further includes the following procedure:
Receiving the radio frequency signal;
19. The interference avoidance transmission system method according to claim 18, wherein the analog reception data is converted into digital reception data.
The invention of claim 28 further includes the following procedures:
28. The interference avoidance transmission system method according to claim 27, wherein the received data is inspected and the extension data of the received data is removed.
The invention of claim 29 is the method of the interference avoidance transmission system according to claim 28, wherein the inspection method is a square root cosine method.
The invention of claim 30 further includes the following steps:
19. The interference avoidance transmission system method according to claim 18, wherein serial reception data is converted into parallel reception data, and the extension data of the reception data is removed.
The invention of claim 31 further includes the following procedures:
19. The interference avoidance transmission system method according to claim 18, wherein the parallel output data is replaced with serial transmission data.
The invention of claim 32 further includes the following procedure:
19. The interference avoidance transmission system method according to claim 18, wherein the output data is equalized.
The invention of claim 33 further includes the following procedures:
19. The interference avoidance transmission system method according to claim 18, wherein the output data is decoded.
The invention of claim 34 is a method of an interference avoidance transmission system according to claim 18, which can be applied to ultra wideband orthogonal frequency division multiplexing.

  The interference avoidance transmission system of the present invention receives first data by an interference processing module provided mainly in a transmission device, adds a plurality of extension data to the first data, generates second data, and generates an interference frequency of the data. A plurality of data in the band is replaced with zero data to generate transmission data, and then the transmission processing module converts the transmission data into a radio frequency signal, transmits it to the receiving device, and receives the radio frequency signal. By deleting the extension data included in the input data of the deletion unit and decoding the corresponding input data by the receiving device, it is possible to avoid the frequency band overlap area and avoid mutual interference of signals.

  The interference avoidance transmission system according to the present invention uses an ultra wideband (UWB) Orthogonal Frequency Division Multiplexing (OFDM) system to avoid the use frequency band of the WiMAX agreement, and the signal has mutual interference in this frequency band. Avoid. However, this is only one preferred embodiment of the present invention, and it should be mentioned that the present invention should not be limited thereby.

  FIG. 1 is a block diagram of a transmitter in a preferred embodiment of the present invention. As shown in the figure, the transmitter 1 of the interference avoidance transmission system of the present invention includes a serial parallel converter 110, a first reverse fast Fourier transform unit 120, an interference processing module 130, a parallel serial converter 140, a filter 150, and transmission processing. The module 160 is configured. The serial / parallel converter 110 receives input data, converts the serial data into parallel data, and transmits the parallel data to the first reverse fast Fourier transform unit 120. The first inverse fast Fourier transform unit 120 receives the parallel data, converts the frequency band input data, generates the first data, and sets it as the time domain data input data.

  In order to improve the analysis of the first data, the interference processing module 130 generates a second data by adding a plurality of extension data to the first data when receiving the first data, and an interference band of the first data The transmission data is generated after replacing the plurality of data with zero data. Among them, the extended data improves the resolution, so when providing a plurality of zero data and replacing the plurality of data in the interference band with zero data, the accuracy of the first data can be improved and the possible interference band can be avoided accurately. .

  The parallel serial converter 140 converts parallel data into serial transmission data. The filter 150 receives serial transmission data and cuts unnecessary noise. The filter 150 is a square root raised cosine filter. The transmission processing module 160 receives the transmission data, converts it to a radio frequency signal, and transmits the radio frequency signal.

  In addition, the interference processing module 130 further includes an extension unit 132, a second fast Fourier transform unit 134, a selection unit 136, and a second reverse fast Fourier transform unit 138. In order to improve the degree of analysis, the extension unit 132 adds the extension data to the first data to generate second data. Of these, the extended data is a plurality of zero data. Furthermore, the larger the extension data, the higher the analysis degree of the second data. The second data is received by the second fast Fourier transform unit 134, the second data in the time domain is converted into the second data in the frequency band, and the third data is generated. The selection unit 136 selects only a plurality of pieces of data in the interference band corresponding to the third data and replaces them with zero data to generate fourth data. The second inverse fast Fourier transform unit 138 converts the fourth data in the time domain into the fourth data in the frequency band to generate transmission data. Among them, the selection unit 136 is provided with a multiplexing device, selects a plurality of data in the interference band of the third data based on the zero tone selection signal, and replaces it with zero data.

  The transmission processing module 160 further includes a digital to analog converter 162, a radio frequency transmitter 164, and a transmitting antenna 166. The digital analog converter 162 converts the transmission data into analog, the radio frequency transmitter 164 converts the analog transmission data into a radio frequency signal, and transmits the radio frequency signal from the transmission antenna 166.

  FIG. 2 is a block diagram of a receiver in a preferred embodiment of the present invention. As shown in the figure, the receiver 2 of the interference avoidance transmission system according to the present invention includes a reception processing module 210, a filter 220, a serial parallel converter 230, a deletion unit 240, a first fast Fourier transform unit 250, an equalizer 260, a parallel serial signal. It comprises a converter 270 and a decoding unit 280. The reception processing module 210 receives the radio frequency signal transmitted from the transmitter and converts the radio frequency signal into a received signal. The filter 220 removes noise from received data. The filter uses a square root raised cosine filter. The serial / parallel converter 230 converts the serial data into parallel received data and transmits it to the deletion unit 240. When the deletion unit 240 deletes the extension data included in the received data, the extension data is added to the first data by the extension unit 132 of the transmission device 1 of FIG. 1 to generate reduction data. The reduced data is converted by the first fast Fourier transform unit 250 to generate output data. The equalizer 260 receives the input data, equalizes the output data, and compensates for the effect on the data transmission channel. The parallel serial converter 270 converts the parallel output data into serial output data. The output data is decoded by the decoding unit 280, and the data transmission is completed.

  In addition, the reception processing module 210 further includes a reception antenna 212, a radio frequency signal receiver 214, and a digital analog converter 216. The radio frequency signal is received from the radio frequency signal receiver 214 by the receiving antenna 212, and the radio frequency signal receiver 214 converts the radio frequency signal into reception data. The digital analog converter 216 receives the analog reception data and the digital reception data.

  FIG. 3 is a frequency band diagram in a preferred embodiment of the present invention. What is shown is an application diagram of ultra-wideband orthogonal frequency division multiplexing. The frequency band of ultra-wideband use is 3.1 GHz to 10.6 GHz, so it overlaps with the frequency of 3.6 GHz per week of WiMAX, and the maximum frequency band used by WiMAX is 20 MHz, so ultra-wideband signal transmission is 20 MHz. It avoids the frequency band, avoids the frequency band using WiMAX, and avoids signal interference. The present invention improves the analysis degree of the input data in the transmission device by adding the extension data. As an example, when the input data is 5, the frequency band of 20 MHz is divided into five frequency bands, and each frequency band is 4 MHz. When the extension data is added to the input data, the resolution of the input data is increased to 10. The frequency band of 20 MHz is divided into 10 frequency bands, and each frequency band is 2 MHz. Thereby, the improvement of the analysis degree of input data can further improve the accuracy of the ultra-wideband technology. That is, a frequency band of 20 MHz can be avoided.

  On the other hand, one stroke of data corresponds to one sinc waveform in the frequency band. The higher the analysis level of the transmission data, the narrower the sinc waveform and the lower the signal strength of the side lobe. For this reason, when the interference signal module shields a predetermined signal, the intensity of the sidelobe signal of the sinc waveform is weakened, and the interference avoidance capability of the present invention is enhanced. As shown in FIG. 3, since the interference avoidance capability according to the present invention is 42 dB, mutual interference of signals can be surely avoided.

It is a block diagram of the transmitter in the Example of this invention. It is a block diagram of the receiver in the Example of this invention. It is a frequency band figure of the Example of this invention.

Explanation of symbols

110 Serial Parallel Converter 120 First Reverse Fast Fourier Transform Unit 130 Interference Processing Module 132 Expansion Unit 134 Second Fast Fourier Transform Unit 136 Selection Unit 138 Second Reverse Fast Fourier Transform Unit 140 Parallel Serial Converter 150 Filter 160 Transmission Processing Module 162 Digital Analog Converter 164 Radio Frequency Signal Transmitter 166 Transmit Antenna 210 Receive Processing Module 212 Receive Antenna 214 Radio Frequency Signal Receiver 216 Digital Analog Converter 220 Filter 230 Serial Parallel Converter 240 Deletion Unit 250 First Fast Fourier Transform Unit 260 Equalizer 270 Parallel Serial Converter 280 Decoding Unit

Claims (34)

A transmission device comprising the following components,
A first inverse fast Fourier transform unit that receives input data and converts the input data into first data;
The interference processing module receives the first data, adds a plurality of extension data to the first data, generates second data, replaces the plurality of data in the interference frequency band of the data with zero data, Generate.
The transmission processing module converts the transmission data into a radio frequency signal, transmits the radio frequency signal,
A receiving device comprising the following components,
Receiving the radio frequency signal by a reception processing module, converting the radio frequency signal into received data;
Deleting the extension data prepared for the received data by a deletion unit, generating return data;
An interference avoidance transmission system, wherein a first Fast Fourier Transform unit converts the reduction data to generate output data. The interference processing module generates, by an extension unit, the extension data by adding the extension data to the first data,
A second Fast Fourier Transform unit that transforms the second data to generate third data;
The selection unit replaces a plurality of data in the interference frequency band of the third data with zero data to generate fourth data,
The interference avoidance transmission system according to claim 1, wherein the fourth data is converted into transmission data by a second reverse fast Fourier transform unit.   3. The interference avoidance transmission system according to claim 2, wherein the selection unit is a multiplexing device.   The interference avoidance transmission system according to claim 1, wherein the extension data is a plurality of zero data. The transmission processing module converts the transmission data into analog transmission data by a digital analog converter,
2. The interference avoidance transmission system according to claim 1, wherein the analog transmission data is converted into the radio frequency signal by a radio frequency signal transmitter, and the radio frequency signal is transmitted by a transmission antenna.   6. The interference avoidance transmission system according to claim 5, wherein the transmission processing module removes noise of the transmission data by a filter and transmits the transmission data to the digital analog converter.   The interference avoidance transmission system according to claim 6, wherein the filter is a square root raised cosine filter.   2. The interference avoidance transmission system according to claim 1, wherein the transmitting device converts the serial input data into parallel input data by a serial parallel converter and transmits the parallel input data to the inverse Fourier transform unit.   2. The interference avoidance transmission system according to claim 1, wherein the transmitting device converts the parallel transmission data into serial transmission data by a parallel serial converter and transmits the serial transmission data to the transmission processing module. The reception processing module receives the radio frequency signal by a transmission antenna;
A radio frequency signal receiver converts the radio frequency signal into the received data,
2. The interference avoidance transmission system according to claim 1, wherein the analog-type received data is converted into digital-type received data by an analog-digital converter.   11. The interference avoidance transmission system according to claim 10, wherein the reception processing module removes noise of the reception data by a filter and transmits the noise to the removal unit.   12. The interference avoidance transmission system according to claim 11, wherein the filter is a square root raised cosine filter.   2. The interference avoidance transmission system according to claim 1, wherein the receiving device converts the serial transmission data into parallel transmission data by a serial parallel converter and transmits the parallel transmission data to the removal unit.   2. The interference avoidance transmission system according to claim 1, wherein the receiving apparatus converts the output data by a parallel serial converter and outputs the output data as serial output data.   The interference avoidance transmission system according to claim 1, wherein the receiving apparatus equalizes the output data with an equalizer.   The interference avoidance transmission system according to claim 1, wherein the receiving apparatus decodes the output data by a decoding unit.   2. The interference avoidance transmission system according to claim 1, which can be applied to ultra-wideband orthogonal frequency division multiplexing. Receiving input data, converting the input data into first data;
Receiving the first data, adding a plurality of extension data to the first data, generating a second data, replacing the plurality of data in the interference frequency band of the data with zero data, generating transmission data;
Converting the transmission data into a radio weekly signal, transmitting the radio weekly signal,
Receiving the radio weekly signal, converting the radio weekly signal into received data;
Deleting the extension data included in the received data to generate return data;
A method of an interference avoidance transmission system, wherein the reduction data is converted to generate output data. In the method of receiving the first data, adding a plurality of extension data to the first data, generating second data, replacing the plurality of data in the interference frequency band with zero data, and generating transmission data, Includes the following steps:
Adding the extension data to the first data to generate second data;
Converting the second data to generate third data;
The selection unit replaces a plurality of data in the interference frequency band of the third data with zero data to generate fourth data,
The method of claim 18, wherein the fourth data is converted into the transmission data.   The interference avoidance transmission system method according to claim 19, wherein a plurality of data in the interference frequency band of the third data is replaced with zero data, and the fourth data is generated by using a multiplexing method.   The method of claim 18, wherein the extension data is a plurality of zero data. The data of the transmission data is converted into a radio frequency signal, and the procedure for transmitting the radio frequency signal further includes the following procedure:
The transmission data is converted into analog transmission data,
Converting the analog transmission data into the radio frequency signal;
19. The method of interference avoidance transmission system according to claim 18, wherein the radio frequency signal is transmitted.   23. The method of the interference avoidance transmission system according to claim 22, further comprising: converting the transmission data after examining the transmission data.   24. The method according to claim 23, wherein the inspection method is a square root cosine method. In addition, the following steps are included:
19. The method of the interference avoidance transmission system according to claim 18, wherein serial input data is replaced with parallel input data, and the input data is converted into first data. In addition, the following steps are included:
19. The interference avoidance transmission system method according to claim 18, wherein the parallel transmission data is converted into serial transmission data, and the transmission data is converted into a radio frequency signal. The procedure for converting the radio frequency signal into reception data further includes the following procedure:
Receiving the radio frequency signal;
19. The method of an interference avoidance transmission system according to claim 18, wherein the analog reception data is converted into digital reception data. In addition, the following steps are included:
28. The method of interference avoidance transmission system according to claim 27, wherein the received data is inspected and the extension data of the received data is removed.   29. The interference avoidance transmission system method according to claim 28, wherein the inspection method is a square root cosine method. In addition, the following steps are included:
19. The method of the interference avoidance transmission system according to claim 18, wherein serial reception data is converted into parallel reception data, and the extension data of the reception data is removed. In addition, the following steps are included:
19. The interference avoidance transmission system method according to claim 18, wherein the parallel output data is replaced with serial transmission data. In addition, the following steps are included:
19. The interference avoidance transmission system method according to claim 18, wherein the output data is equalized. In addition, the following steps are included:
The method of the interference avoidance transmission system according to claim 18, wherein the output data is decoded.   19. The method of interference avoidance transmission system according to claim 18, which can be applied to ultra wideband orthogonal frequency division multiplexing.

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