Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L27/00—Modulated-carrier systems
  • H04L27/26—Systems using multi-frequency codes
  • H04L27/2601—Multicarrier modulation systems
  • H04L27/2602—Signal structure
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04B—TRANSMISSION
  • H04B11/00—Transmission systems employing ultrasonic, sonic or infrasonic waves
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L27/00—Modulated-carrier systems
  • H04L27/26—Systems using multi-frequency codes
  • H04L27/2601—Multicarrier modulation systems
  • H04L27/2626—Arrangements specific to the transmitter only
  • H04L27/2627—Modulators
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L27/00—Modulated-carrier systems
  • H04L27/26—Systems using multi-frequency codes
  • H04L27/2601—Multicarrier modulation systems
  • H04L27/2647—Arrangements specific to the receiver only
  • H04L27/2649—Demodulators
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; ELECTRIC HEARING AIDS; PUBLIC ADDRESS SYSTEMS
  • H04R5/00—Stereophonic arrangements
  • H04R5/04—Circuit arrangements, e.g. for selective connection of amplifier inputs/outputs to loudspeakers, for loudspeaker detection, or for adaptation of settings to personal preferences or hearing impairments
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L1/00—Arrangements for detecting or preventing errors in the information received
  • H04L1/004—Arrangements for detecting or preventing errors in the information received by using forward error control

Definitions

• Modulation device modulation method, demodulation device, and demodulation method
• the present invention relates to a sound wave information communication technique for transmitting information by sound waves.
• Patent Document 1 Japanese Patent Document 1
• a frequency masking threshold is calculated using a psychoacoustic model, and a spread signal that is spread over the entire frequency band by multiplying a transmission signal by a spreading code sequence is set to a masking threshold value or less. In such a way, they are superimposed.
• Patent Document 1 International Publication No. 02/45286 Pamphlet
• Patent Document 1 In the method described in Patent Document 1, it is necessary to increase the spreading gain of a spreading code in order to extract a transmission signal from speech 'music'. However, the amount of information that can be transmitted is reduced by increasing the spreading gain. If the transmission signal level is suppressed to a level that cannot actually be perceived by human hearing, the method described in Patent Document 1 can transmit information of only a few bits per second.
• the present invention has been made to solve the above-described problems, and is not unpleasant to human hearing. Based on the level, information is transmitted by an audible sound wave and the bit rate of the transmission information is It is an object to improve.
• the modulation device includes a modulation unit that generates a modulation signal by modulating a carrier wave in an audible sound band with a baseband signal, and a masker sound that makes the modulation signal difficult to hear when transmitted together with the modulation signal. It is characterized by comprising a masker sound generating means for generating an output masker signal and an acoustic signal generating means for generating an acoustic signal by adding the masker signal to the modulation signal.
• the modulation means modulates an audible sound band carrier wave with a baseband signal to generate a modulation signal
• the masker sound generation means is transmitted together with the modulation signal.
• a signal generation step for generating a masker signal that is output as a masker sound that makes the modulated signal difficult to hear.
• an acoustic signal generating means that adds a masker signal to the modulated signal to generate an acoustic signal.
• the modulation means modulates the audible sound band carrier wave with the baseband signal to generate the modulation signal, so that the information contained in the baseband signal is converted into the audible sound wave. It can be put in a state where transmission is possible at a higher bit rate.
• the masker sound generating means generates a masker signal that is output as a masker sound that makes it difficult to hear the modulated signal when transmitted along with the modulated signal, and the acoustic signal generating means converts the masker signal into a modulated signal.
• an audible sound wave for transmitting information can be transmitted in a state where it is difficult to hear by a masker sound of a masker signal. That is, it is not unpleasant to human hearing, and based on the level, information can be transmitted with an audible sound wave and the bit rate of transmitted information can be improved.
• the masker tone generation means comprises each masker signal inserted into the modulation signal as a sine wave, and at least some of the continuous masker tone frequencies of each masker tone have a predetermined pattern. It is also preferable to select the frequency of the masker signal so that
• the modulation device converts the amplitude of the carrier wave in the audible sound band into the spectral envelope of the acoustic signal. And a modulation means for generating a modulated signal by modulating the carrier wave with a baseband signal, and an acoustic signal for generating a synthesized acoustic signal by replacing the frequency band component of the carrier wave in the acoustic signal with the modulated signal generated by the modulation means And a signal generating means.
• the modulation unit adjusts the amplitude of the carrier wave in the audible sound band to the vector envelope of the acoustic signal and modulates the carrier wave with the baseband signal to generate a modulation signal;
• the acoustic signal generation means includes an acoustic signal generation step of generating a synthesized acoustic signal in which a component of a frequency band of a carrier wave in the acoustic signal is replaced with a modulation signal generated in the modulation step.
• the modulation means matches the amplitude of the carrier wave in the audible sound band with the spectral envelope of the acoustic signal and modulates the carrier wave with the baseband signal to generate the modulated signal.
• a signal corresponding to an audible sound wave that produces a sound based on the sound is generated, and information contained in the baseband signal can be transmitted at a higher bit rate by the audible sound wave.
• the acoustic signal generation means replaces the frequency band of the carrier wave with the modulation signal to generate a synthesized acoustic signal, so that the sound can be produced based on the acoustic signal and the bit rate of the transmission information can be further improved to transmit the information.
• the modulation means preferably amplifies the power of the spectrum of the frequency to the threshold when there is a frequency that does not satisfy the predetermined threshold based on the audible level in the spectrum envelope of the acoustic signal. Masashi.
• the demodulating device of the present invention duplicates a signal frame of a transmission signal modulated by a frequency multiplexing method and connects a plurality of signal frames including the duplicated signal frame and the transmitted signal frame. And a demodulating means for demodulating the signal frame by performing a Fourier transform on the plurality of signal frames connected by the connecting means, and detecting a carrier frequency shift of the transmission signal in the plurality of signal frames Fourier-transformed by the demodulating means. The transmission signal based on the detection means and the deviation of the carrier frequency detected by the detection means. And a correction means for correcting the carrier frequency.
• the concatenating means duplicates the signal frame of the transmission signal modulated by the frequency multiplexing method, and concatenates a plurality of signal frames including the duplicated signal frame and the transmitted signal frame.
• a demodulating step for demodulating the signal frame by Fourier transforming the plurality of signal frames concatenated in the concatenating step, and a plurality of signal frames in which the detecting means is Fourier transformed in the demodulating step.
• Detecting means for detecting a shift in the carrier frequency of the transmission signal and correction means for correcting the carrier frequency of the transmission signal based on the shift in the carrier frequency detected in the detection step.
• the concatenating means duplicates the signal frame of the transmission signal modulated by the frequency multiplexing method, and Fourier transforms the plurality of concatenated signal frames.
• the width of the signal orthogonal frequency can be reduced. That is, the frequency resolution can be improved.
• the detection means can accurately detect the shift of the carrier frequency of the transmission signal in the Fourier transformed signal frame, and the carrier frequency can be corrected by the correction means.
• the demodulation device of the present invention demodulates an acoustic signal including a modulation signal and a masker signal that is output as a masker sound that makes the modulation signal difficult to hear when transmitted together with the modulation signal.
• An apparatus comprising: removal means for removing a masker signal from an acoustic signal; and demodulation means for demodulating the acoustic signal from which the masker signal has been removed by the removal means.
• a signal included in a modulation signal can be extracted from an acoustic signal including the modulation signal and a masker signal.
• the demodulator of the present invention comprises a modulation signal and a masker output as a masker sound that is composed of a frequency associated with the frequency band of the carrier wave and makes it difficult to hear the modulation signal when transmitted together with the modulation signal.
• a demodulator for demodulating an acoustic signal including a single signal, storage means for storing the frequency band of the carrier wave and the frequency of the masker signal in association with each other, and a Fourier transform of the masker signal to generate a masker sound.
• the detecting means for detecting the frequency, the frequency of the masker signal detected by the detecting means and the frequency stored in association with the storing means
• a demodulating means for demodulating the acoustic signal in a band.
• the frequency band of the carrier wave and the frequency of the masker sound are stored in association with each other, and the detection means detects the frequency of the masker signal, so that the frequency band of the carrier wave is grasped. Can provide necessary information. Therefore, the demodulation means demodulates the acoustic signal in the frequency band stored in association with the frequency of the masker signal detected by the detection means and the storage means, so that the demodulation can be performed accurately.
• the present invention it is not unpleasant for human hearing! Based on the level, it is possible to transmit information with an audible sound wave and to improve the bit rate of the transmitted information.
• FIG. 1 is a configuration diagram of an acoustic signal transmission system according to a first embodiment.
• FIG. 2 is a configuration diagram of an acoustic signal receiving system according to the first embodiment.
• FIG. 3 is a configuration diagram of a modulation device according to the first embodiment.
• FIG. 5 is a flowchart of a modulation method according to the first embodiment.
• FIG. 6 is a configuration diagram of a demodulation device according to the first embodiment.
• FIG. 7 is a configuration diagram of an acoustic signal transmission system according to a second embodiment.
• FIG. 8 is a configuration diagram of a modulation device according to a second embodiment.
• FIG. 9 is a diagram for explaining a modulation method according to the second embodiment.
• FIG. 10 is an example of a frequency utilization arrangement of a transmission acoustic signal output from a modulation apparatus according to a second embodiment.
• FIG. 11 is a flowchart of a modulation method according to the second embodiment.
• FIG. 12 is a configuration diagram of a demodulation device according to a second embodiment.
• FIG. 13 is a configuration diagram of a modulation device according to a third embodiment.
• FIG. 14 is an example of a frequency utilization arrangement of transmission acoustic signals output from the modulation apparatus according to the third embodiment.
• FIG. 15 is a configuration diagram of a demodulating device according to a third embodiment.
• FIG. 16 is a diagram for explaining a demodulation method according to the third embodiment.
• FIG. 17 is a diagram for explaining a demodulation method according to the third embodiment.
• Synthesized sound signal 41—SZP converter, 42... carrier wave, 43 guard time signal generator, 44 masker sound generator, 45 frame sync signal generator, 46—DZA converter, 47 ⁇ Pilot signal ⁇ Acoustic signal generation unit, 101 AZD conversion unit, 102 ⁇ Frame synchronization unit, 103 ⁇ ⁇ ⁇ Masker sound ⁇ Guard time removal unit, ⁇ 104 ⁇ Carrier wave, 105 PZS conversion unit, 106 ... Bandpass filter, 107 ... Frame synchronization signal, 108-OFDM modulation signal, 109 ... Phase correction unit, llO OFDM frame concatenation unit, 111 ... Subcarrier selection unit, 11 2 ... Demodulation unit, 113 ... Storage unit 114 ... detection unit, 115 ... guard time removal unit, 116 ... demodulation unit, RSI, RS2 "'acoustic signal transmission system, TS1, TS2"' acoustic signal transmission system.
• the system of the first to third embodiments according to the present invention is a sound wave information communication system for transmitting information by an audible sound wave.
• first to third embodiments will be described with reference to the drawings.
• FIG. 1 shows a configuration diagram of the acoustic signal transmission system TS1 according to the first embodiment
• FIG. 2 shows a configuration diagram of the acoustic signal reception system RS1 according to the first embodiment.
• the sound wave information communication system according to the present embodiment includes the acoustic signal transmission system TS1 and the acoustic signal reception system RS1 shown in FIGS.
• the acoustic signal transmission system TS1 outputs a transmission data signal 1T including information to be transmitted on the sound wave 7.
• the acoustic signal receiving system RS1 receives the sound wave 7 output from the acoustic signal transmission system TS1, and extracts the transmission data signal 1T from the sound wave 7.
• the acoustic signal transmission system TS1 audiblely transmits an error correction coding device 2 that encodes the transmission data signal IT with an error correction code, and an encoded transmission signal 3 (baseband signal) that is encoded with the error correction code. It includes a modulation device 4A that converts a transmission acoustic signal 5A (acoustic signal), which is a band acoustic signal, and a speaker 6 that reproduces the transmission acoustic signal 5A as an audible sound wave 7.
• a modulation device 4A that converts a transmission acoustic signal 5A (acoustic signal), which is a band acoustic signal
• a speaker 6 that reproduces the transmission acoustic signal 5A as an audible sound wave 7.
• the acoustic signal receiving system RS 1 receives a sound wave 7 and generates a received acoustic signal 9 A (acoustic signal) that is an acoustic signal, and demodulates the received acoustic signal 9 A to generate a received transmission signal 11.
• a demodulating device 10A that extracts data and an error correction decoding device 12 that corrects errors in the received transmission signal 11 and outputs a transmission data signal 1R are configured.
• FIG. 2 shows a configuration diagram of the modulation device 4A according to the first embodiment.
• the modulation device 4A includes an S / P conversion unit 41, a modulation unit 51 (modulation unit), a guard time signal generation unit 43, a masker sound generation unit 44 (masker sound generation unit), and an acoustic signal generation unit 52 (acoustic signal). Generating means), a frame synchronization signal generating unit 45, and a DZA converting unit 46.
• the SZP conversion unit 41 receives the encoded transmission signal 3 and converts the encoded transmission signal 3 of a single bit stream into a parallel bit stream.
• the SZP conversion unit 41 outputs the converted parallel bit stream to the modulation unit 51.
• Modulation section 51 modulates carrier wave 42 of each frequency with each parallel transmission bit of the input parallel bit stream, and synthesizes the modulated carrier wave 42 signal to form a signal frame (modulated signal).
• the modulation unit 51 modulates using the OFDM modulation method. That is, the frequency of the carrier 42 (carrier frequency) is an orthogonal frequency that is orthogonal to each other. Further, the transport wave 42 is a sound wave in the audible sound band.
• the modulation unit 51 assigns each parallel transmission bit as a spectrum coefficient of each carrier wave frequency, and modulates the carrier wave 42 by performing an inverse Fourier transform. Then, the modulation unit 51 combines the modulated carrier waves 42 of each frequency to form a signal frame. Modulation section 51 outputs the formed signal frame to guard time signal generation section 43.
• the guard time signal generation unit 43 duplicates a rear section of the input signal frame and performs duplication.
• the manufactured rear section is connected to the front of the signal frame as a guard time signal.
• This guard time signal can avoid multipath interference such as reflected waves.
• the guard time signal generation unit 43 outputs the signal frame and the generated guard time signal to the masker sound generation unit 44.
• the masker sound generation unit 44 generates a masker signal.
• a masker signal is a signal that is output as a masker sound of a signal frame and a guard time signal when transmitted as a sound wave 7 together with a signal frame and a guard time signal.
• the masker sound is a sound that makes it difficult for humans to hear by masking the sound when the signal frame and guard time signal are transmitted.
• the masker tone generator 44 selects a sine wave of at least one frequency as a masker tone and generates a masker signal.
• the masker sound generator 44 selects the frequency of the masker signal so that the frequency of at least a part of the continuous masker sounds of each masker sound has a predetermined pattern. More specifically, the masker sound generator 44 selects the frequency of the masker sound to be inserted so that a series of melody is formed when each masker sound included in each signal frame is transmitted.
• the masker tone generation unit 44 may synthesize a plurality of sine waves to generate a masker tone, and change the tone of the masker tone. Further, the masker sound generation unit 44 selects a frequency or a frequency pattern associated with the frequency band of the carrier wave 42 as the frequency of the masker sound. That is, the generated masker signal includes information indicating the frequency band of the carrier wave 42.
• the masker sound generation unit 44 outputs the generated masker signal, signal frame, and guard time signal to the acoustic signal generation unit 52.
• the acoustic signal generator 52 adds a masker signal to the signal frame to generate an acoustic signal.
• the acoustic signal generation unit 52 adds a masker signal to the front of the guard time signal and the rear of the signal frame to generate an acoustic signal. That is, the acoustic signal generation unit 52 generates an acoustic signal in which the masker signal is inserted.
• the acoustic signal generation unit 52 first fades out the front signal frame in front of the masker sound section to prevent the masker sound, the guard time, and the signal frame from being discontinuous in phase. An acoustic signal is generated so that it fades in. Then, at the end of the masker sound, the acoustic signal generator 52 fades out the masker sound and fades in the guard time. Generate an acoustic signal.
• the acoustic signal generating unit 52 generates a fade-out signal that fades out the front signal frame by copying the front of the front signal frame and connecting the replicas behind.
• the acoustic signal generation unit 52 generates a fade-in signal that fades in the guard time by generating the guard time long in advance.
• the acoustic signal generation unit 52 outputs the generated acoustic signal to the frame synchronization signal generation unit 45.
• the frame synchronization signal generation unit 45 generates a frame synchronization signal and adds it to the acoustic signal.
• the frame synchronization signal is a signal for specifying the location of each of the signal frame, guard time signal, and masker signal included in the acoustic signal on the receiving side.
• the frame synchronization signal is a PN (pseudo noise) signal modulated with an M-sequence code.
• the frame synchronization signal generation unit 45 outputs the acoustic signal with the frame synchronization signal added to the DZA conversion unit 46.
• the DZA conversion unit 46 converts the acoustic signal into an analog signal and outputs the analog signal to the speech force 6 as the transmission acoustic signal 5A.
• FIG. 4 shows an example of frequency use of the signal frame, guard time signal, masker signal, and frame synchronization signal included in the transmission acoustic signal 5A.
• the beginning of the frame sync signal should be coincident with the start point of a masker note.
• the spread spectrum frame sync signal is transmitted in the low frequency range with a lot of environmental noise.
• the masker, guard time, and signal frame are transmitted in the high frequency range. That is, the frame synchronization signal is transmitted in a frequency band different from the frequency band for transmitting the signal frame, the guard time, and the masker signal.
• FIG. 5 is a flowchart of the modulation method according to the first embodiment.
• the encoded transmission signal 3 is also converted into a parallel bit stream by the SZP converter 41 (S11). Then, each carrier wave 42 is modulated (inverse Fourier transform) by the modulation unit 51 with each parallel transmission bit of the parallel bit stream, and the modulated carrier waves 42 are combined to form a signal frame (S12).
• the rear section of the formed signal frame is duplicated by the guard time signal generation unit 43 and connected in front to generate a guard time signal (S13). Guard time is generated Then, the masker signal power is generated by the masker sound generator 44 (S14). The generated masker signal force is added to the front of the guard time and the rear of the signal frame by the acoustic signal generation unit 52 to generate an acoustic signal (S15).
• a PN (pseudo noise) signal modulated by the M-sequence code is generated by the frame synchronization signal generation unit 45 and added to the acoustic signal as a frame synchronization signal (S16).
• the acoustic signal force generated in this way is converted to an analog signal by the DZA conversion unit 46 and output as a transmission acoustic signal 5A.
• the transmission acoustic signal 5A output in this way is output as a sound wave 7 from the speaker 6, and plays a masker sound based on the masker signal and propagates the signal in space.
• the sound wave 7 is received by the microphone 8.
• the sound wave 7 received by the microphone 8 is output as a received acoustic signal 9A to the demodulator 10A.
• FIG. 6 shows a configuration diagram of the demodulator 10A according to the first embodiment.
• the demodulator 10A includes an AZD conversion unit 101, a frame synchronization unit 102, a masker sound / guard time removal unit 103 (removal unit), a demodulation unit 112 (demodulation unit), a storage unit 113 (storage unit), and a detection unit 114 (detection). Means) and a PZS converter 105.
• the AZD conversion unit 101 samples the received acoustic signal 9A and converts it into a digital signal.
• the AZD conversion unit 101 outputs the converted digital signal to the frame synchronization unit 102.
• Frame synchronization section 102 correlates the input digital signal with the PN signal modulated by the M-sequence code while shifting by one sample and several samples, and recognizes the point with the highest correlation value as the frame synchronization point. Divide into frame units. The frame synchronization unit 102 outputs the divided signal divided into frame units to the masker sound guard time removal unit 103.
• the masking tone 'guard time removal unit 103 removes the masker signal and the guard time from the divided signal for each divided frame, and extracts a signal frame.
• the masker one-tone guard time removal unit 103 outputs the extracted signal frame to the demodulation unit 112.
• the masker tone guard time removal unit 103 outputs the masker signal removed from the signal frame to the detection unit 114.
• the demodulator 112 demodulates the signal frame with each carrier wave 104. Input to demodulator 112 When signal frames having different frequency bands of the carrier wave 104 are mixed, the demodulation unit 112 demodulates corresponding to the frequency band of the carrier wave 104. In other words, the demodulation unit 112 selects the frequency band of the carrier wave 104 to be demodulated using the functions of the storage unit 113 and the detection unit 114.
• the storage unit 113 stores the frequency band of the carrier wave 104 and the frequency of the masker signal in association with each other.
• the frequency of the masker signal may be a specific masker signal included in the acoustic signal, or may be a frequency pattern constituting a series of melodies.
• the storage unit 113 stores the frequency band A of the carrier wave 104 and the frequency a of the masker signal in association with each other.
• the storage unit 113 stores the frequency band B of the carrier wave 104 and the frequency pattern information b indicating the frequency pattern of the masker signal in association with each other.
• the detection unit 114 performs a Fourier transform on the masker signal input from the masker sound guard time removal unit 103 to detect the frequency of the masker signal.
• the detection unit 114 outputs information indicating the frequency of the detected masker signal to the demodulation unit 112.
• the demodulation unit 112 When receiving information indicating the frequency of the masker signal, the demodulation unit 112 receives the frequency of the carrier signal 104 to be demodulated based on the frequency of the input masker signal and the frequency band stored in association with the storage unit 113. Determine the band. Then, the demodulation unit 112 determines and demodulates the signal frame with the carrier 104 in the frequency band.
• the demodulation unit 112 demodulates, for example, by the OFDM demodulation method, the signal frame is Fourier-transformed.
• Demodulation section 112 outputs the spectral coefficient of each carrier 104 obtained by demodulation to PZS conversion section 105.
• PZS conversion section 105 extracts parallel transmission bits from the input spectral coefficients.
• the P / S conversion unit 105 converts the extracted parallel transmission bits into a single bit stream and outputs it as a received transmission signal 11.
• the demodulator 10A configured as described above operates as follows. First, when the received acoustic signal 9A is input, the received acoustic signal 9A is converted into a digital signal by the AZD conversion unit 101. The converted digital signal power is divided into frames by the frame synchronization unit 102. The divided signal is removed from the masker signal and guard time signal for each frame by the masker sound guard time removal unit 103, and a signal frame is extracted. It is. The removed masker signal is Fourier transformed by the detection unit 114 to detect the frequency of the masker sound.
• Each of the extracted signal frames is demodulated by the demodulation unit 112 using the carrier 104 in the frequency band stored by the storage unit 113 in association with the detected frequency of the masker sound.
• the PZS converter 105 also extracts parallel transmission bits from the spectral coefficient power of the carrier wave 104 obtained by demodulation.
• the extracted parallel transmission bits are converted into a single bit stream by the PZS conversion unit 105 to generate a reception transmission signal 11.
• the modulation unit 51 generates a signal frame by modulating the carrier wave 42 in the audible sound band with the parallel transmission bit 3, so that it is included in the parallel transmission bit by the audible sound wave. Information can be transmitted at a higher bit rate.
• the masker sound generation unit 44 generates a masker signal that is output as a masker sound for listening to the transmission sound of the signal frame
• the acoustic signal generation unit 52 adds the masker signal to the signal frame to generate an acoustic signal. Since the signal is generated, it is possible to transmit an audible sound wave that transmits information in a state in which it is difficult to hear. That is, it is possible to transmit information with an audible sound wave based on a level that is not unpleasant to human hearing and to improve the bit rate of the transmitted information.
• the masker tone generation unit 44 configures each masker signal inserted into the modulation signal as a sine wave, and at least a part of the continuous masker tone frequency of each masker tone has a predetermined frequency. It is also preferable to select the masker signal frequency to be a pattern. By doing so, it is possible to maintain the bit rate of the transmission information and to select the sound pattern played by a masker sound during the transmission of the acoustic signal.
• the masker sound generator 44 is selected during the transmission of the acoustic signal by selecting the frequency of the masker sound so that a series of melodies are generated when each masker sound included in each signal frame is transmitted. You can play melodies.
• the masker sound 'guard time removing unit 103 removes the received modulation signal force masker signal divided into frames, extracts a signal frame, and demodulates the signal. Since 112 demodulates the signal frame, the acoustic signal power including the signal frame and the masker signal can also extract information contained in the signal frame.
• the storage unit 113 stores the frequency band of the carrier wave 104 and the frequency of the masker sound in association with each other, and the detection unit 114 detects the frequency of the masker signal. It is possible to provide information necessary for grasping. Therefore, the demodulating unit 112 demodulates the acoustic signal by using the frequency of the masker signal detected by the detecting unit 114 and the frequency band stored in association with the storing unit 113, so that demodulation can be performed accurately.
• the sound wave information transmission system is a system for transmitting information by reproducing a transmission signal from the power in parallel with voice and music.
• the sound wave information transmission system of the present embodiment includes an acoustic signal transmission system and an acoustic signal reception system.
• FIG. 7 shows a configuration diagram of an acoustic signal transmission system TS2 according to the second embodiment.
• the acoustic signal transmission system TS2 of this embodiment includes an error correction coding device 2, a modulation device 4B, and a speaker 6.
• the input signal of the modulation device 4B includes an audio signal 13 such as voice or music in addition to the encoded transmission signal 3.
• the difference between the acoustic signal transmission system TS2 according to the present embodiment and the acoustic signal transmission system TS1 according to the first embodiment is that a modulation device 4B is provided instead of the modulation device 4A, and the modulation device 4B inputs the acoustic signal 13 It is a point.
• the acoustic signal receiving system of the present embodiment has the same configuration as the acoustic signal receiving system RS1 of the first embodiment, and includes a demodulating device 10B instead of the demodulating device 10A.
• the modulation device 4B converts the encoded transmission signal 3 so that it can be transmitted as an acoustic signal, synthesizes it with the acoustic signal 13, and outputs a synthesized acoustic signal 14B.
• the synthesized acoustic signal 14B is received as the received acoustic signal 9B by the microphone 8 of the acoustic signal receiving system.
• Demodulation apparatus 10B extracts received transmission signal 11 from received acoustic signal 9B. Subsequently, the modulation device 4B and the demodulation device 10B will be described in detail.
• FIG. 8 shows a configuration diagram of a modulation device 4B according to the second embodiment.
• Modulator 4B includes S / P converter 41, spectrum envelope amplitude adjuster 47, modulator 53 (modulator), guard time signal A generation unit 43, a frame synchronization signal generation unit 45, a bandpass filter 48, an acoustic signal generation unit 54 (acoustic signal generation means), and a DZA conversion unit 46 are configured.
• the functions of the SZP conversion unit 41, the guard time signal generation unit 43, the frame synchronization signal generation unit 45, and the DZA conversion unit 46 are the same as those included in the modulation device 4A according to the first embodiment, and thus description thereof is omitted.
• the spectrum envelope amplitude adjustment unit 47 receives the acoustic signal 13 and performs Fourier transform on the input acoustic signal to calculate the spectral envelope of the acoustic signal 13. That is, the spectrum envelope amplitude adjustment unit 47 calculates the amplitude of each frequency of the acoustic signal 13. Then, the vector envelope amplitude adjustment unit 47 outputs the calculation result of the spectrum envelope to the modulation unit 53. Further, the spectrum envelope amplitude adjustment unit 47 outputs the input acoustic signal 13 to the bandpass filter 48.
• Modulation section 53 adds transmission bits known in the reception side (demodulation apparatus 10 B) in parallel as pilot signal 49 to the parallel bit stream input from SZP conversion section 41. Next, based on the spectrum envelope calculation result output from the spectrum envelope amplitude adjustment unit 47, the modulation unit 53 applies the amplitude of each frequency of the acoustic signal 13 to each bit of the parallel transmission bits including the pilot signal 49. Information is added correspondingly. Then, the modulation unit 53 modulates the carrier wave 42 with each transmission bit to which the amplitude information of the acoustic signal 13 is added.
• the modulation unit 53 matches the amplitude of each carrier wave 42 with the spectrum envelope of the acoustic signal 13 and modulates each carrier wave 42 with each bit of the parallel transmission bits including the pilot signal 49.
• the modulation unit 53 modulates using the OFDM modulation method. That is, the modulation unit 53 uses orthogonal frequencies that are orthogonal to each other as the frequency of the carrier wave 42, assigns a vector envelope and parallel transmission bits as spectral coefficients of each carrier frequency, and performs modulation by inverse Fourier transform.
• the modulation unit 53 when the spectrum envelope indicated by the calculation result includes a frequency that does not satisfy a predetermined threshold value based on the audible level, the modulation unit 53 amplifies the spectrum power of that frequency to the threshold value.
• the threshold is set, for example, below the audible level or below the allowable range.
• the modulation unit 53 combines the modulated signals of the carrier waves 42 to form a signal frame. Modulation section 53 outputs the formed signal frame to guard time signal generation section 43.
• the band-pass filter 48 removes the frequency band component of the carrier wave 42 from the input acoustic signal 13 and outputs it to the acoustic signal generation unit 54.
• the acoustic signal generation unit 54 superimposes the frame signal output from the frame synchronization signal generation unit 45, the guard time signal, the frame synchronization signal, and the acoustic signal 13 output from the bandpass filter 48.
• a synthetic acoustic signal 14B is generated. That is, the acoustic signal generation unit 54 generates the composite acoustic signal 14B by replacing the frequency band component of the carrier wave 42 in the acoustic signal 13 with the modulation signal.
• the acoustic signal generation unit 54 outputs the generated synthesized acoustic signal 14B to the DZA conversion unit 46.
• FIG. 8 (a) shows an example of the spectrum of the acoustic signal 13.
• the bandpass filter 48 removes the frequency band D component of the carrier wave 42 from the acoustic signal 13 shown in FIG. 8 (a).
• the solid line portion indicates the acoustic signal 13 from which the component of the frequency band D is removed, and the dotted line indicates the frequency band D from which the component is removed.
• the modulation unit 53 matches the amplitude of each carrier 42 with the spectrum envelope, and modulates each carrier 42 to generate a modulated signal 42F.
• the acoustic signal generation unit 54 superimposes the modulated signal 42F and the acoustic signal 13 from which the frequency band D component has been removed to generate a combined modulated signal 14B.
• FIG. 10 shows an example of frequency usage of the signal frame, guard time signal, masker signal, and frame synchronization signal included in the synthesized acoustic signal 14B.
• the start of the frame sync signal should be coincident with the start time of the guard time.
• the spread spectrum frame synchronization signal is transmitted in the low frequency range where the acoustic signal 13 component remains.
• the guard time and signal frame are transmitted in the high frequency range. That is, the frame synchronization signal is transmitted in a frequency band different from the frequency band for transmitting the signal frame and the guard time.
• FIG. 11 is a flowchart of the modulation method according to the second embodiment.
• the encoded transmission signal 3 is also converted into a parallel bit stream by the SZP conversion unit 41 (S21). Further, the spectrum envelope force of the acoustic signal 13 is calculated by the vector envelope amplitude adjusting unit 47 (S22). Acoustic signal below threshold 1 When there is a frequency of 3, the power of the corresponding frequency is amplified by the modulation unit 53 (S23).
• the amplitude information 1S pilot signal 49 of each frequency of the acoustic signal 13 indicated in the calculation result of the spectral envelope is added in correspondence with each bit of the parallel transmission bits.
• the carrier wave 42 is modulated by each transmission bit to which the amplitude information of the acoustic signal 13 is added. That is, the amplitude of the carrier wave 42 is adjusted by the modulation unit 53 in accordance with the spectrum envelope of the acoustic signal 13, and each carrier wave 42 is modulated (inverse Fourier transform) by each transmission bit. Then, the modulated signal of each carrier wave 42 is combined to form a signal frame (S24).
• the rear section of the formed signal frame is duplicated by the guard time signal generation unit 43 and connected in front to generate a guard time signal (S25).
• a PN (pseudo noise) signal modulated by the M-sequence code is generated by the frame synchronization signal generation unit 45 and added to the signal frame as a frame synchronization signal (S26).
• the acoustic signal 13 from which the frequency band of the carrier wave 42 has been deleted and the signal frame are superimposed by the acoustic signal generation unit 54 to generate a synthesized acoustic signal (S27).
• the generated synthesized sound signal 14B force is converted into an analog signal by the DZA converter 46 and output (S28).
• the synthesized acoustic signal 14B output in this way is output as a sound wave 7 from the speaker 6, plays a melody based on the acoustic signal 13, and propagates the signal through the space. Then, the sound wave 7 is received by the microphone 8 included in the acoustic signal receiving system. The sound wave 7 received by the microphone 8 is output to the demodulator 10B as a received acoustic signal 9B.
• FIG. 12 shows a configuration diagram of the demodulator 10 B according to the second embodiment.
• the demodulation device 10B includes an AZD conversion unit 101, a bandpass filter 106, a frame synchronization unit 102, a guard time removal unit 115, a demodulation unit 112, a phase correction unit 109, and a PZS conversion unit 105.
• the AZD conversion unit 101, the frame synchronization unit 102, and the PZS conversion unit 105 have the same functions as those included in the demodulator 10A according to the first embodiment described above, and thus description thereof is omitted.
• the bandpass filter 106 receives the digital signal output by the AZD conversion unit 101, and divides the input digital signal into a band having a frame synchronization signal component and a band having a signal frame component.
• a signal in a band having a frame synchronization signal component is referred to as a frame synchronization signal 107
• a signal in a band having a signal frame component is referred to as an OFDM modulation signal 108.
• Bandpass filter 106 outputs frame synchronization signal 107 and OFDM modulated signal 108 to frame synchronization section 102, respectively.
• Frame synchronization section 102 obtains a correlation with a PN signal modulated with an M-sequence code while shifting frame synchronization signal 107 by one sample and several samples, and recognizes a point having the highest correlation value as a frame synchronization point. . Then, frame synchronization section 102 divides OFDM modulated signal 108 into frame units according to the recognized frame synchronization point. Frame synchronization section 102 outputs the divided OFDM modulated signal 108 to guard time removal section 115.
• the guard time removing unit 115 removes the guard time for each divided frame and extracts a signal frame.
• the guard time removal unit 115 outputs the extracted signal frame to the demodulation unit 116.
• Demodulation section 116 demodulates the extracted signal frame with each carrier 104.
• the demodulator 1 16 performs Fourier transform on the signal frame and demodulates the signal frame using the OFDM demodulation method.
• Phase correction section 109 extracts a pilot signal from demodulated carrier wave 104. Then, the phase correction unit 109 detects the signal change of the pilot signal by comparing the spectrum coefficient of the extracted pilot signal with the spectrum coefficient of the known pilot signal 49. Then, the phase correction unit 109 corrects the signal of the other carrier 104 based on the detected signal change. The phase correction unit 109 outputs the corrected signal to the PZS conversion unit 105.
• PZS conversion section 105 extracts parallel transmission bits from the input signal. Then, the P / S conversion unit 105 converts the extracted parallel transmission bits into a single bit stream and outputs it as a received transmission signal 11.
• the demodulator 10B configured as described above operates as follows. First, when the received acoustic signal 9B is input, the received acoustic signal 9B is converted into a digital signal by the AZD conversion unit 101. The converted digital signal is converted to frame sync signal 107 and OFDM modulation. The signal 108 is divided by the band pass filter 106. The OFDM modulation signal 108 is divided into frame units by the frame synchronization unit 102 based on the frame synchronization signal 107. The guard time removing unit 115 removes the guard time signal for each frame from the divided digital signal, and a signal frame is extracted.
• Each extracted signal frame is demodulated by demodulation section 116 using carrier 104.
• the pilot signal is extracted from the demodulated signal frame by the phase correction unit 109, and the signal of the other carrier 104 is also corrected for the changing force between the extracted pilot signal and the known pilot signal 49.
• parallel transmission bits are extracted from the spectral coefficient of the carrier wave 104 by the PZS conversion unit 105.
• the extracted parallel transmission bits are converted into a single bit stream by the P / S conversion unit 105, and the reception transmission signal 11 is generated.
• the modulation unit 53 matches the amplitude of the carrier wave 42 in the audible sound band with the spectrum envelope of the acoustic signal 13, and modulates the carrier wave 42 with the baseband signal to generate a modulation signal. Therefore, an audible sound wave that produces a sound based on the acoustic signal 13 is generated, and a signal included in the baseband signal can be transmitted at a higher bit rate by the audible sound wave.
• the acoustic signal generation unit 54 replaces the frequency band of the carrier wave 42 with the modulation signal to generate a synthesized acoustic signal, so that the sound based on the acoustic signal 13 can be played and the transmission information bit rate can be improved to transmit information. .
• the modulation unit 53 when there is a frequency that does not satisfy a predetermined threshold value based on the audible level in the spectrum envelope of the acoustic signal 13, the modulation unit 53 amplifies the power of the spectrum of the frequency to the threshold value. It is possible to improve the S / N ratio of the transmission signal without generating unpleasant sound.
• the phase correction unit 109 corrects the signal by estimating the change in the signal of the carrier wave 42 modulated by a known signal (for example, a pilot signal) and estimating the change in the signal of the other carrier 42. Changes in the amplitude or phase of the signal that occur during signal propagation can be corrected. Therefore, errors in signal identification due to signal changes can be reduced.
• the modulation device 4A modulates the specific carrier wave 42 included in the signal frame with the pilot signal 49, and the demodulation device 10B detects the change in the signal of the specific carrier wave 42 to another carrier wave 42. Suppose you want to correct the signal.
• the sound wave information transmission system is a system for transmitting a transmission signal and a masker sound in parallel with voice and music and reproducing and transmitting from a speaker as in the second embodiment.
• this sound wave information transmission system corrects a small deviation in sampling frequency between the transmission side and the reception side on the reception side.
• the sound wave information transmission system includes an acoustic signal transmission system (transmission side) and an acoustic signal reception system (reception side), similarly to the sound wave information transmission system of the second embodiment. Is done.
• the modulation device 4C of the present embodiment converts the encoded transmission signal 3 so that it can be transmitted as a sound wave, synthesizes it with the acoustic signal 13, and outputs a synthesized acoustic signal 14B.
• the demodulator 10C extracts the received transmission signal 11 from the received acoustic signal 9C.
• the acoustic signal transmission system of the present embodiment has the same configuration as the acoustic signal transmission system RS2 of the second embodiment, and includes a modulation device 4C instead of the modulation device 4B.
• the acoustic signal receiving system of the present embodiment has the same configuration as the acoustic signal receiving system of the second embodiment, and includes a demodulating device 10C instead of the demodulating device 10B. Subsequently, the modulation device 4C and the demodulation device 10C will be described in detail.
• FIG. 13 shows the configuration of the modulation device 4C according to the third embodiment.
• the modulation device 4C includes an S / P conversion unit 41, a spectrum envelope amplitude adjustment unit 47, a modulation unit 53, a guard time signal generation unit 43, a masker sound generation unit 44, an acoustic signal generation unit 52, a frame synchronization signal generation unit 45, A band-pass filter 48, an acoustic signal generation unit 54, and a DZA conversion unit 46 are provided. These components are the same as the components included in the modulators 4B and 4C of the first and second embodiments. Since these functions are provided, detailed description of each component will be omitted.
• the encoded transmission signal 3 is input to the SZP conversion unit 41 and converted into a single bit stream encoded signal transmission signal 3 force S parallel bit stream.
• a pilot signal 49 is added in parallel to the converted parallel bit stream by the modulation unit 53.
• the acoustic signal 13 is input by the spectral envelope amplitude adjusting unit 47, and the spectral envelope is calculated.
• each carrier 42 is adjusted according to the spectral envelope of the acoustic signal 13 and each bit of the parallel transmission bits including the pilot signal 49 is adjusted.
• the carrier wave 42 is modulated by the modulation unit 53.
• the modulated signal of each carrier 42 is combined by the modulation unit 53 to form a signal frame.
• the rear section of the signal frame is duplicated by the guard time signal generation unit 43 and connected as a guard time signal in front of the signal frame.
• a masker tone masking signal for masking the signal frame and the guard time signal is generated by the masker tone generator 44.
• the generated masker signal is added by the acoustic signal generator 52 in front of the guard time signal and behind the signal frame. Then, it is generated by the frame synchronization signal power frame synchronization signal generating unit 45 for specifying the location of the signal frame, guard time signal, and masker signal on the receiving side, and is added to the signal frame.
• the component of the carrier frequency band is removed from the acoustic signal 13 input by the spectrum envelope amplitude adjusting unit 47 by the band pass filter 48.
• the acoustic signal 13 from which the frequency band of the carrier wave 42 has been removed, the signal frame, the guard time signal, the masker signal, and the force acoustic signal generation unit 54 are superimposed to generate a synthesized acoustic signal.
• the generated synthesized acoustic signal 14C is converted into an analog signal by the DZA converter 46 and output.
• FIG. 12 shows an example of the frequency utilization arrangement of the signal frame, guard time signal, masker signal, frame synchronization signal, and acoustic signal 13 included in the synthesized acoustic signal 14C thus generated.
• the frame synchronization signal is transmitted in a frequency band different from that of the carrier wave 42. In other words, a spectrum spread frame in the low frequency range where the components of the acoustic signal 13 remain. Transmit synchronization signal.
• a masker tone forms a melody using both low and high frequencies.
• the guard time and the signal frame are transmitted in the high sound range.
• the head of the frame sync signal should be the same as the head of the masker note.
• a masker sound may be inserted at an arbitrary location in a band different from the carrier frequency band.
• the guard time signal and the previous signal frame are adjacent to each other, and the phase of the guard time signal and the phase of the previous signal frame are discontinuous. Therefore, a masker sound is inserted in the vicinity of the boundary between the previous signal frame and the guard time signal so as to mask the phase discontinuous portion or the force for smoothing the phase discontinuous portion.
• FIG. 15 shows the configuration of the demodulator 10 C according to the third embodiment.
• the demodulation device 10C is a device that demodulates the received acoustic signal 9C modulated by the frequency multiplexing method.
• the received acoustic signal 9C is a signal modulated by the OFDM modulation method.
• the demodulator 10C includes an AZD conversion unit 101, a bandpass filter 106, a frame synchronization unit 102, a masker 'guard time removal unit 103, an OFDM frame connection unit 110 (connection means), a demodulation unit 116, and a subcarrier selection unit 111. (Detection means and correction means), a phase correction unit 109, and a PZS conversion unit 105.
• the components included in the demodulation devices 10A and 10C have the same function in the demodulation device 10C.
• FIGS. 16 and 17 are diagrams for explaining the demodulation method according to the third embodiment.
• Fig. 16 (a) shows the combined signal of the masker signal, guard time signal, and OFDM modulation signal.
• the masker's guard time removal unit 103 removes the masker signal and the guard time signal from the combined signal power shown in FIG. 16 (a), and extracts a signal frame.
• Figure 16 (b) shows one signal frame.
• the masker tone 'guard time removal unit 103 outputs the extracted signal frame to the OFDM frame concatenation unit.
• the OFDM frame concatenation unit 110 duplicates the signal frame, and concatenates the duplicated signal frames. For example, the OFDM frame concatenation unit 110 duplicates one signal frame into four as shown in FIG. 16 (c) and concatenates the four signal frames. OFDM frame series The concatenating unit 110 outputs the concatenated signal frames to the demodulating unit 116.
• FIG. 17 (a) shows the signal spectrum when the signal frames are Fourier transformed one by one as in the conventional case.
• the horizontal axis indicates the frequency, and the bold scale indicates the frequency of the carrier wave 42 in the modulation device 4C.
• Fig. 17 (a) shows the ideal signal spectrum when the frequency of the carrier 104 that identified the signal spectrum (the center frequency of the signal spectrum in Fig. 17) matches each frequency of the carrier 42. Shown in a).
• Fig. 17 (b) shows the signal spectrum when Fourier transform is applied to a signal frame that is duplicated and connected in four.
• the fine line on the horizontal axis indicates the frequency of the carrier 104 that identifies the signal spectrum.
• FIG. 17 (b) shows an ideal signal spectrum when the frequency of the carrier 104 that identifies the signal spectrum matches the frequency of the carrier 42, as in FIG. 17 (a).
• the frequency resolution in Fig. 17 (b) is four times the frequency resolution in Fig. 17 (a).
• the frequency resolution can be increased by duplicating signal frames and connecting them to increase the Fourier transform target time.
• Fig. 17 (c) shows the signal spectrum when four signal frames that are duplicated and concatenated are subjected to Fourier transform, and the frequency of the carrier 104 that identifies the signal spectrum deviates from the frequency of the carrier 42. Indicates. In this case, the frequency resolution is high, so the shifted signal The orthogonal frequency identifying the vector does not interfere with the orthogonal frequency corresponding to the adjacent signal. Therefore, each signal spectrum can be identified.
• the frequency resolution can be increased by performing Fourier transform on a plurality of signal frames obtained by duplicating signal frames. Since the frequency resolution is high, each signal spectrum can be identified even when the frequency of the carrier 104 for identifying the signal spectrum is shifted.
• subcarrier selecting section 111 detects the frequency shift of carrier 104 in the demodulated signal spectrum (transmission signal), and the signal spectrum based on the detected frequency shift of carrier 104.
• the frequency of the carrier wave 104 is corrected. That is, when the subcarrier selection unit 111 detects a shift in the frequency of the carrier wave 104 in the signal spectrum, the subcarrier selection unit 111 corrects the frequency force of the carrier wave 104 to the closest frequency of the carrier wave 42. Since the frequency shift of the carrier wave 104 of the signal spectrum differs for each frequency, it is preferable to correct for each signal spectrum.
• the subcarrier selection unit 111 performs correction by estimating the ratio of deviation from the frequency shift of some of the carrier waves 104. This method is effective because the frequency shift of the carrier 104 often increases or decreases at a certain rate from the frequency of the carrier wave 42. By this method, larger frequency shifts and Doppler shifts can be corrected.
• the demodulator 10B configured as described above operates as follows.
• the received acoustic signal 9B is converted into a digital signal by the AZD conversion unit 101.
• the converted digital signal power is divided into a frame synchronization signal 107 and an OFDM modulation signal 108 by a band pass filter 106.
• the OFDM modulation signal 108 is divided into frames by the frame synchronization unit 102 based on the frame synchronization signal 107. From the divided digital signal, the masker and guard time signal is removed for each frame by the masker sound guard time removing unit 103, and a signal frame is extracted.
• the extracted signal frame force is duplicated and concatenated by the OFDM frame concatenation unit 110.
• a plurality of concatenated signal frames are demodulated by the demodulation unit 116.
• Demodulated signal Is corrected by the frequency force subcarrier selection unit 111 of the carrier 104 of the signal spectrum.
• the pilot signal is extracted from the demodulated signal frame by the phase correction unit 109, and the phase of the other carrier wave 104 is corrected for the changing power of the pilot signal.
• the parallel transmission bits of the spectral coefficient power of the carrier wave 104 are extracted by the PZS conversion unit 105.
• the extracted parallel transmission bits are converted into a single bit stream by the P / S conversion unit 105, and the reception transmission signal 11 is generated.
• the modulation unit 53 matches the amplitude of the carrier wave 104 with the spectrum envelope of the acoustic signal 13 and modulates the carrier wave 104 with the encoded transmission signal 3 to generate a signal frame.
• an audible sound wave that produces a sound based on an acoustic signal is generated, and a signal included in the baseband signal is transmitted by the audible sound wave at a higher bit rate.
• the masker sound generation unit 44 generates a masker signal that is output as a masker sound that makes it difficult to hear the sound during transmission of the signal frame and adds it to the signal frame.
• the composite acoustic signal is generated by replacing the frequency band component of the carrier wave 104 with the modulation signal (signal frame), it is possible to transmit the audible sound wave including information in a state that it is difficult to hear by the masker sound of the masker signal. The That is, it is possible to transmit information with an audible sound wave based on a level that is not unpleasant to human hearing and improve the bit rate of the transmitted information.
• the plurality of signal frames duplicated and concatenated by the OFDM frame concatenating unit 110 are Fourier-transformed.
• the frequency range can be narrowed. That is, the frequency resolution can be improved.
• the subcarrier selection unit 111 can accurately detect the frequency shift of the carrier wave 104 of the transmission signal in the Fourier-transformed signal frame and correct the frequency of the carrier wave 104.
• the present invention uses a sound wave information communication technology for transmitting information by sound waves, and uses human sound. Based on the level, information is transmitted with an audible sound wave and the bit rate of the transmitted information is improved.

Landscapes

• Engineering & Computer Science (AREA)
• Signal Processing (AREA)
• Computer Networks & Wireless Communication (AREA)
• Physics & Mathematics (AREA)
• Acoustics & Sound (AREA)
• Transmitters (AREA)
• Telephonic Communication Services (AREA)

Priority Applications (2)

Applications Claiming Priority (2)

Publications (1)

Family

ID=37942620

Family Applications (1)

Country Status (5)

Cited By (7)

Families Citing this family (37)

Citations (13)

Family Cites Families (15)

• 2005
  • 2005-10-07 JP JP2005295526A patent/JP4398416B2/ja not_active Expired - Fee Related
• 2006
  • 2006-10-02 WO PCT/JP2006/319669 patent/WO2007043376A1/ja not_active Ceased
  • 2006-10-02 EP EP06811017A patent/EP1947793A4/en not_active Ceased
  • 2006-10-02 US US12/066,836 patent/US8498860B2/en not_active Expired - Fee Related
  • 2006-10-02 CN CNA2006800250848A patent/CN101218768A/zh active Pending
  • 2006-10-02 CN CN2010101450939A patent/CN101827064B/zh not_active Expired - Fee Related

Patent Citations (13)

Non-Patent Citations (1)

Also Published As

Similar Documents

Legal Events