Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04J—MULTIPLEX COMMUNICATION
  • H04J3/00—Time-division multiplex systems
  • H04J3/02—Details
  • H04J3/06—Synchronising arrangements
  • H04J3/0602—Systems characterised by the synchronising information used
  • H04J3/0605—Special codes used as synchronising signal
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04B—TRANSMISSION
  • H04B1/00—Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
  • H04B1/69—Spread spectrum techniques
  • H04B1/7163—Spread spectrum techniques using impulse radio
  • H04B1/7183—Synchronisation
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L25/00—Baseband systems
  • H04L25/38—Synchronous or start-stop systems, e.g. for Baudot code
  • H04L25/40—Transmitting circuits; Receiving circuits
  • H04L25/49—Transmitting circuits; Receiving circuits using code conversion at the transmitter; using predistortion; using insertion of idle bits for obtaining a desired frequency spectrum; using three or more amplitude levels ; Baseband coding techniques specific to data transmission systems
  • H04L25/4902—Pulse width modulation; Pulse position modulation

Definitions

• the present invention relates to a wireless communication apparatus using a pulse modulation signal.
• FIG. 12 is a block diagram showing a configuration of a conventional pulse radio communication device described in Patent Document 1.
• a conventional pulse radio communication apparatus 1200 includes an amplifier 1202 for amplifying an RF signal received by an antenna 1201, a filter 1203 for removing an unnecessary signal, and an analog encoding means 1204 for analogizing the signal.
• a splitter 1 205 which splits the signal, a plurality of delay devices 1206 1207 1208 which delay the signal, multipliers 1209 1210 1211 which multiply the signal, integrators 1212 1213 1214 which integrate the time, correlation Reception synchronization control unit 1217 that performs synchronization determination and delay control according to the above, phase delay means 1218 that delays the phase of the signal, and a main reception wavelet code generator that modulates the phase delay signal and diffuses with the same spreading code. 1216 and a splitter 1215 which branches the output of the main reception wavelet code generator 1216 into three and outputs the result to multipliers 1209, 1210 and 1211.
• the received RF signal is amplified to an amplitude necessary for demodulation by amplifier 1202, an unnecessary frequency band outside the band is removed by filter 1203, and an analog code is generated by analog coding means 1204.
• This signal is branched by a splitter 1205 and a delay unit 1206 And 1207 and 1208 output three delayed signals, that is, a signal delayed by time L, a signal delayed by time L + Y, and a signal delayed by time LY.
• These three signals are multiplied by the reference pulse signals generated by the main receive wavelet code generator 1216 by multipliers 1209, 1210, 1211 [hereby, integrators 1212, 1213, 1214 [note, symbol respectively Integrate the corresponding time.
• the reception synchronization control unit 1217 determines synchronization according to the correlation of each signal, and controls the phase delay unit 1218 to output the decoded data 1219 while sliding synchronization.
• the reception path signal at time L is used as a reference for correlation, and when the signal at time L + Y becomes higher correlation than the signal at time L, the tracking period is delayed by phase delay means 1218 to When the signal of time L ⁇ Y is higher at the time of the correlation, the phase delay means 1218 is adjusted to synchronize with the transmission data signal by advancing the tracking period.
• Patent Document 1 JP-A-2003-535552 (148, FIG. 27)
• a conventional pulse radio communication apparatus for establishing synchronization by correlating a waveform based on a synchronization frame in a received signal every time communication is performed, and then performing data demodulation, and
• the level of the correlation pulse is increased by the interference wave such as the multipath where the transmission speed of the actual information is lower or the power of other devices.
• the interference wave is determined by determining the level of the correlation pulse in stages or by using a plurality of receiving systems as shown in the prior art (FIG. 12).
• a configuration to remove is also proposed, there is a problem that the judgment flow becomes complicated, the equipment configuration becomes large, the power consumption increases, and the equipment also becomes expensive.
• An object of the present invention is to provide a pulse modulation type transmitter and a pulse modulation type receiver capable of high-speed data transmission capable of exchanging data.
• the receiving device switches the synchronization method as appropriate according to the synchronization state, thereby providing a plurality of reception systems.
• Another object of the present invention is to provide a low power consumption pulse modulation type transmitter, pulse modulation type receiver and system.
• a pulse modulation type receiving apparatus comprises a second RF input signal as a received RF data signal and a first template signal used to generate a frame synchronization signal of the first RF input signal.
• a pulse modulation type receiving apparatus including a frame synchronization unit that receives a RF input signal of a signal and outputs a correlation reception data signal that is a correlation between a first RF input signal and a second RF input signal, comprising: The section synchronizes the first template synchronization timing adjustment section for extracting the first template signal from the second RF input signal and the second template signal with the first template signal, and outputs the template signal.
• the first template signal is selected, and according to the synchronization state of the frame, First temp Frame signal generation for generating a frame synchronization signal using the template signal switching unit for switching and outputting to the second template signal and the first or second template signal output from the template signal switching unit And a second frame synchronization timing adjustment unit that synchronizes the frame synchronization signal with the first RF input signal and outputs a correlated reception data signal, and the second frame synchronization timing
• the adjustment unit is a frame synchronization correlation determination unit that outputs a template switching instruction signal to the template switching unit when the correlation value between the first RF input signal and the frame synchronization signal reaches a predetermined value.
• the template signal switching unit receives the template switching signal and disconnects the first template signal power to the second template signal. It has a configuration to perform the replacement operation.
• the frame synchronization unit is configured to receive the first RF input signal, which is the received RF data signal, and the second RF input signal having the template signal for generating the frame synchronization signal.
• the frame synchronization signal switching unit selects a frame synchronization signal using the first template signal of the second RF input signal.
• the second frame synchronization timing adjustment unit uses the frame synchronization signal to achieve synchronization pull-in of the first RF input signal.
• the second thin While synchronization between the first RF input signal and the frame synchronization signal using the first template signal is established in the bolt synchronization timing adjustment unit, the template signal generation unit is operated in the template signal generation unit.
• the correlation judgment unit for frame synchronization in the second timing adjustment unit for frame synchronization detects the correlation between the first RF input signal and the signal for frame synchronization, and when the correlation value reaches a predetermined value, Send a frame synchronization signal switching instruction signal to the frame synchronization signal switching unit. Furthermore, the frame synchronization signal switching unit performs an input switching operation from the first template signal to the second template signal in accordance with the frame synchronization signal switching instruction signal. Furthermore, the second frame synchronization timing adjustment section synchronizes the frame synchronization signal using the second template signal with the first RF input signal, and outputs a decoded data signal.
• the frame synchronization establishment operation is performed by switching from the frame synchronization signal using the first template signal to the frame synchronization signal using the second template signal according to the frame synchronization state.
• the time required for establishing frame synchronization can be shortened.
• by shortening the time required to establish frame synchronization a large amount of data can be received, so high-speed data transmission can be performed.
• the first RF input signal and the second RF input signal are started to be input to the frame synchronization unit in the frame synchronization state.
• the frame synchronization timing adjustment unit detects the presence or absence of the RF data pulse that constitutes the first RF input signal, and the first state in the pulse capture state for achieving synchronization pull-in, and the second frame synchronization state.
• a second state which is a pulse phase capture state for establishing synchronization of phase levels of wave elements forming an RF data pulse, and the correlation determination unit for frame synchronization determines a first RF input signal.
• the first template It was subjected to synchronous detection using No., in the second state, and has a structure having means for performing synchronous detection using the second template signal.
• the frame synchronization unit in the pulse capture state, receives the first template signal.
• the pulse phase capture state synchronous detection using the second template signal can be performed, and the time required to establish frame synchronization can be shortened.
• the time required to establish frame synchronization a large amount of data can be received, so high-speed data transmission can be performed.
• the pulse modulation type receiving apparatus of the present invention has a configuration in which the second RF input signal is a signal transmitted in a frequency band different from that of the first RF input signal.
• the frame synchronization unit can reduce the influence of the first RF input signal from the second RF input signal transmitted in the frequency band different from that of the first RF input signal.
• the template signal can be extracted, and frame synchronization can be established using the first template signal less affected by the first RF input signal, and the time required to establish frame synchronization can be shortened. can do. Further, by shortening the time required for establishing frame synchronization, a large amount of data can be received, and high-speed data transmission can be performed.
• the template signal switching unit in the pulse modulation type receiving apparatus receives the template switching signal and performs the switching operation to the first template signal power and the second template signal.
• the power supply to the timing adjustment section for synchronization is shut off!
• the frame synchronization unit receives the template signal switching unit force template switching signal, performs the switching operation from the first template signal to the second template signal, and then performs the first frame synchronization.
• Power consumption of the pulse modulation type receiving apparatus can be reduced by stopping the power supply supplied to the timing adjustment unit in a predetermined portion or the entire first symbol synchronization timing adjustment unit.
• the pulse modulation type receiving device of the present invention when the power supply to the first frame synchronization timing adjustment unit is stopped, the second RF input signal is input again, or If the RF frame synchronization holding signal for performing synchronization error correction is input from the communication partner at a predetermined interval, there is a configuration having means for resuming power supply to the first frame synchronization timing adjustment unit. I will speak.
• the symbol synchronization unit of the pulse modulation type receiving apparatus controls the power supply supplied to the first frame synchronization timing adjustment unit by a predetermined portion or the first frame synchronization. By stopping the entire timing adjustment unit, the power consumption of the pulse modulation type receiving apparatus can be reduced. Also, after frame synchronization is established, frame synchronization is maintained after frame synchronization has been established using an RF frame synchronization signal sent subsequently after a predetermined time has elapsed or an RF frame synchronization holding signal received at predetermined time intervals. It is possible to shorten the time required to establish reframe synchronization for maintaining frame synchronization.
• the decoded data signal is received in response to the correlated received data signal and the RF symbol synchronization timing signal having the first timing signal used to generate the symbol synchronization signal.
• the symbol synchronization unit further includes a first symbol synchronization timing adjustment unit that extracts a first timing signal from the RF symbol synchronization timing signal, and a second timing signal, When the input of the correlation reception data signal and the timing signal for RF symbol synchronization to the clock recovery unit and the symbol synchronization unit synchronized with the timing signal 1 is started, the first timing signal is selected. And a timing signal switching unit that switches and outputs the first timing signal to the second timing signal according to the symbol synchronization state.
• a symbol generation unit that generates an RF symbol synchronization signal using the first and second timing signals output from the timing signal switching unit, and synchronizes the symbol synchronization signal with the correlation reception data signal
• a second symbol synchronization timing adjustment unit for outputting a second symbol synchronization timing signal, the second symbol synchronization timing adjustment unit, when the correlation value between the correlated reception data signal and the symbol synchronization signal reaches a predetermined value.
• a correlation determination unit for symbol synchronization that outputs a timing switching instruction signal to the timing signal switching unit, the timing signal switching unit receiving the timing switching instruction signal, the first timing signal strength, and the second timing.
• the timing signal switching unit performs timing for RF symbol synchronization. Select the first timing signal that the signal has To choose. Then, the symbol generation unit generates a symbol synchronization signal based on the first timing signal. Then, the second symbol synchronization timing adjustment unit pulls in synchronization of the correlation reception data signal using the symbol synchronization signal. Also, while synchronization between the correlation reception data signal and the symbol synchronization signal is established in the second symbol synchronization timing adjustment unit, the second timing generated in the clock reproduction unit in the clock recovery unit. The signal is synchronized with the first timing signal.
• the correlation determination unit for symbol synchronization in the second timing adjustment unit for symbol synchronization detects the correlation between the correlation reception data signal and the signal for symbol synchronization, and the timing when the correlation value reaches a predetermined value, Send a timing switching instruction signal to the signal switching unit. Furthermore, in the timing signal switching unit, an input switching operation is performed from the first timing signal to the second timing signal according to the timing switching instruction signal. Furthermore, the second symbol synchronization timing adjustment unit synchronizes the symbol synchronization signal using the second timing signal with the correlated reception data signal, and outputs a decoded data signal.
• the timing signal switching unit can switch to the first timing signal or the second timing signal, and the symbol synchronization establishing operation can be performed, and the time required for symbol synchronization establishment can be achieved. Can be shortened. In addition, by shortening the time required to establish symbol synchronization, a large amount of data can be received, so high-speed data transmission can be performed.
• the timing signal switching unit when the timing signal switching unit receives the timing switching instruction signal and performs switching operation to the first timing signal strength second timing signal, It has a configuration having means for stopping the power supply to the timing adjustment section for symbol synchronization.
• the timing signal switching unit receives the timing switching signal and performs the switching operation to the first timing signal strength second timing signal
• the first symbol synchronization is performed.
• Power consumption of the pulse modulation type receiving apparatus can be reduced by stopping the power supply supplied to the timing adjustment section for the predetermined part or the entire first symbol synchronization timing adjustment section.
• the RF symbol synchronization timing signal is input again. In this case, or when the RF symbol synchronization timing holding signal is inputted with a communication partner at predetermined time intervals, the power supply to the first symbol synchronization timing adjustment unit is reopened.
• the symbol synchronization unit transmits the first symbol synchronization signal until the RF symbol synchronization timing signal or the RF symbol synchronization timing holding signal received at predetermined time intervals is transmitted.
• Power consumption of the pulse modulation type receiving apparatus can be reduced by stopping the power supply supplied to the timing adjustment section for the predetermined part or the entire first symbol synchronization timing adjustment section. .
• the symbol synchronization is established after the symbol synchronization is established using the RF symbol synchronization timing signal that is subsequently sent or the RF symbol synchronization timing holding signal that is sent at predetermined time intervals. Therefore, the time required for establishing resynchronization for maintaining symbol synchronization can be shortened.
• a pulse modulation type receiving apparatus includes a second RF input signal as a received RF data signal and a template signal used for generating a frame synchronization signal of the first RF input signal.
• a pulse modulation type receiving apparatus including a frame synchronization unit that receives a RF input signal of a signal and outputs a correlation reception data signal that is a correlation between the first and second RF input signals.
• a first frame synchronization timing adjustment unit that extracts a template signal from a second RF input signal; a frame synchronization signal generation unit that generates a frame synchronization signal based on the template signal;
• a variable delay unit that outputs a delayed reception RF data signal obtained by delaying an RF input signal for a predetermined time and a frame synchronization unit start inputting the first RF input signal and the second RF input signal ,
• the frame synchronization signal switching unit that switches to the frame synchronization signal power and the delayed reception RF data signal according to the frame synchronization state, and the first RF input signal, the frame synchronization signal switching unit.
• a second frame synchronization timing adjustment unit that synchronizes the frame synchronization signal output from the delay reception RF data signal and outputs a correlation reception data signal, and the second frame synchronization timing adjustment unit
• the frame synchronization signal switching unit transmits the frame synchronization signal to the frame synchronization signal.
• the frame synchronization signal switching unit receives the frame synchronization signal switching instruction signal and switches to the frame synchronization signal power delayed reception RF data signal. It has a configuration to operate.
• the frame synchronization unit is configured to receive the first RF input signal, which is a received RF data signal, and the second RF input signal having a template signal for generating a frame synchronization signal.
• the frame synchronization signal switching unit selects a frame synchronization signal using the template signal of the second RF input signal.
• the second frame synchronization timing adjustment unit uses the frame synchronization signal to achieve synchronization pull-in of the first RF input signal.
• the correlation judgment unit for frame synchronization in the timing adjustment unit for second frame synchronization detects the correlation between the first RF input signal and the signal for frame synchronization, and when the correlation value reaches a predetermined value, the frame A frame synchronization signal switching instruction signal is sent out to the synchronization signal switching unit. Furthermore, the frame synchronization signal switching unit switches the frame synchronization signal using the template signal of the second RF input signal to the delayed reception RF data signal according to the frame synchronization signal switching instruction signal. Do the action. Further, the second frame synchronization timing adjustment section synchronizes the delayed received RF data signal with the first RF input signal, and outputs a decoded data signal.
• the frame synchronization signal using the template signal can be switched to the delayed reception RF data signal, and frame synchronization establishment operation can be achieved, and the time required for frame synchronization establishment can be shortened. be able to . Also, by shortening the time required to establish frame synchronization, a large amount of data can be received, so high-speed data transmission can be performed.
• the first RF input signal and the second RF input signal have an input to the frame synchronization unit.
• the second frame synchronization timing adjustment unit detects a presence or absence of an RF data pulse that constitutes the first RF input signal, and a first state in a pulse capture state for achieving synchronization pull-in;
• a second state which is a pulse phase capture state in which the timing adjustment unit for frame synchronization aims to establish synchronization of the phase level of the wave element forming the RF data pulse, and the correlation determination unit for frame synchronization Correlation between RF input signal and frame synchronization signal
• the value reaches a predetermined value, it is determined that the first state should be shifted to the second state, and a template switching instruction signal is sent to the template switching unit, and in the first state, the template signal is transmitted.
• the configuration has means for performing synchronous
• the frame synchronization unit can perform synchronous detection using the template signal in the pulse capture state, and can perform synchronous detection using the first RF input signal in the pulse phase capture state.
• the time required to establish frame synchronization can be shortened.
• by shortening the time required to establish frame synchronization a large amount of data can be received, so high-speed data transmission can be performed.
• the first frame synchronization timing adjustment is performed when the frame synchronization signal power is also switched to the delayed reception RF data signal in the frame synchronization signal switching unit.
• the unit has a configuration with means for stopping the operation.
• the frame synchronization unit receives the frame synchronization signal switching unit power frame synchronization signal switching signal, and after performing a switching operation from the frame synchronization signal to the delayed reception RF data signal, To reduce the power consumption of the pulse modulation type transmitting apparatus by stopping the power supply supplied to the frame synchronization timing adjustment section in a predetermined portion or the entire first frame synchronization timing adjustment section. Can.
• the frame synchronization unit of the pulse modulation type reception device of the present invention performs synchronization with low accuracy with the second RF input signal, and performs high accuracy synchronization with the first RF input signal. have.
• sparse synchronization is performed in a communication system with a low rate and a communication system, and synchronization is performed with high accuracy in a communication system with a high rate and a communication system as needed.
• the power can be reduced, and by performing sparse synchronization at a constant time interval, the accuracy of starting synchronization can also shorten the time to establish synchronization.
• the pulse modulation type transmitting apparatus of the present invention applies predetermined symbols to transmission data, a signal for frame synchronization, and a timing signal for symbol synchronization, and transmits data for symbol transmission and frame synchronization.
• Signal and the symbol / symbol synchronization timing signal A symbolizing unit to be generated and a predetermined modulation are applied to the symbolized transmission data, and the signal is up-converted to a radio frequency to generate an RF data signal having a first RF input signal to be input to a frame synchronization unit of the communication partner.
• An RF data signal transmission unit and an RF data signal having a second RF input signal which is subjected to predetermined modulation on a symbolized frame synchronization signal, upconverted to a radio frequency, and input to a frame synchronization unit of a communication partner.
• the frame synchronization signal and the symbol / symbol synchronization timing signal are subjected to predetermined modulation, up-converted to a radio frequency, and the RF symbol synchronization timing signal input to the symbol synchronization unit of the communication partner is generated. It has a configuration having an RF synchronization signal transmission unit.
• the RF data signal transmission unit performs predetermined symbolization on transmission data, then performs predetermined modulation and up-converts to radio frequency, and performs frame synchronization of the communication partner's pulse-modulated receiver.
• An RF data signal may be generated having a first RF input signal to be input to the unit.
• the RF synchronization signal transmission unit performs predetermined symbol modulation on the frame synchronization signal, then performs predetermined modulation, and up-compensates to the radio frequency, and the frame of the communication partner's pulse modulation type receiving apparatus After an RF frame synchronization signal having a second RF input signal input to the synchronization unit is generated, and a predetermined symbol signal is applied to the symbol synchronization timing signal, a predetermined modulation is performed, and the radio frequency is up-converted.
• an RF symbol synchronization timing signal to be input to the symbol synchronization section of the communication partner pulse modulation type receiving apparatus.
• the pulse modulation type receiving apparatus at the other end of the communication party transmits the transmission data, the frame synchronization signal, the RF data signal having the symbol synchronization timing signal, the RF frame synchronization signal, and the RF symbol synchronization timing signal.
• the time required for frame synchronization establishment and symbol synchronization establishment in the pulse modulation type receiving apparatus can be shortened.
• the signal transmission section for RF synchronization of the pulse modulation type transmission apparatus of the present invention has a configuration having a means for transmitting the timing signal for RF symbol synchronization in a frequency band different from that of the RF frame synchronization signal. doing.
• the pulse modulation type transmitting apparatus can transmit the timing signal for RF symbol synchronization and the signal for RF frame synchronization in different frequency bands having little influence with each other, and the pulse of the communication partner is
• RF symphon The symbol synchronization and frame synchronization can be established based on the timing signal for RF synchronization and the signal for RF frame synchronization, and the time required for establishing frame synchronization and symbol synchronization can be shortened. Also, by shortening the time required for establishing frame synchronization and symbol synchronization, a large amount of data can be transmitted, so high-speed data transmission can be performed.
• the signal transmission unit for RF synchronization of the pulse modulation type transmitting apparatus of the present invention has a configuration having means for transmitting an RF frame synchronization holding signal and an RF symbol synchronization timing holding signal at predetermined time intervals. I have it.
• the nors modulation transmitter can transmit the RF frame synchronization holding signal and the RF symbol synchronization timing holding signal at predetermined time intervals, and the RF frame synchronization holding signal and the RF symbol synchronization can be transmitted.
• the pulse modulation type transmitting device is stopped by stopping the power supply supplied to the RF synchronization signal transmission unit in a predetermined portion or the entire RF synchronization signal transmission unit while not transmitting the timing holding signal. To reduce power consumption.
• the RF data signal transmission unit and the RF synchronization signal transmission unit of the pulse modulation type transmission device further include an RF data signal, an RF frame synchronization signal, and an RF symbol synchronization timing signal.
• the RF frame synchronization holding signal and the RF symbol synchronization timing holding signal it has a configuration including means having a waveform selection unit that assigns wavelets having signal waveforms that can be separated from each other.
• wavelets having signal waveforms that can be separated from each other can be transmitted in the same frequency band, so RF frame synchronization signals, RF symbol synchronization timing signals, and RF frame synchronization, which are separate transmission signals other than data signals, can be transmitted. It becomes possible to transmit the holding signal and the timing holding signal for RF symbol synchronization in the same frequency band as the data signal or other separate transmission signal, and using the frequency band to be prepared for each separate transmission signal, Since data signals can be transmitted, frequency utilization efficiency can be improved, and as a result, high-speed data transmission can be performed.
• the waveform selection unit of the pulse modulation type transmitting apparatus comprises an RF frame synchronization signal, an RF symbol synchronization timing signal, an RF frame synchronization holding signal, and an RF symbol signal. It has a configuration having means for using different wavelets for one or more of the timing holding signals.
• wavelets having signal waveforms that can be separated from each other can be transmitted in the same frequency band, so RF frame synchronization signals, RF symbol synchronization timing signals, and RF frame synchronization, which are separate transmission signals other than data signals, can be transmitted. It becomes possible to transmit the holding signal and the timing holding signal for RF symbol synchronization in the same frequency band as the data signal or other separate transmission signal, and using the frequency band to be prepared for each separate transmission signal, Since data signals can be transmitted, frequency utilization efficiency can be improved, and as a result, high-speed data transmission can be performed.
• the RF frame synchronization signal of the pulse modulation type transmitting apparatus of the present invention may include data for device authentication.
• the data portion for authentication is not required for the data signal for communication, and it is not necessary to reduce the data rate.
• the pulse modulation type transmitting apparatus of the present invention at least two data rates of the RF data signal, the RF frame synchronization signal, and the RF symbol synchronization timing signal are different.
• the above configuration makes it possible to narrow the occupied band of low rate signals and reduce the frequency band to be used by changing the data rate of each signal. In this case, cooperation with low rate other pulse communication is also included.
• the RF synchronization signal transmission unit has a configuration for transmitting at least one of the RF data signal, the RF frame synchronization signal, and the RF symbol synchronization timing signal! / Scold.
• the present invention shortens the time required to establish synchronization, and can transmit and receive data more quickly than the start of communication, and has the effect of enabling high-speed data transmission, and a pulse modulation type receiving device and pulse modulation type receiving device. Can be provided. Also, there are multiple reception systems It is possible to provide a pulse modulation type transmitting apparatus, a pulse modulation type receiving apparatus, and a system, which have the effect of achieving low power consumption of the synchronization unit while having the configuration described above.
• FIG. 1 is a block diagram showing the configuration of a pulse modulation type receiving apparatus according to a first embodiment of the present invention.
• FIG. 2 A block diagram showing the configuration of a pulse modulation type transmitting apparatus according to a first embodiment of the present invention.
• FIG. 3 A block diagram showing the configuration of a pulse modulation type receiving apparatus according to a second embodiment of the present invention.
• FIG. 4 A block diagram showing the configuration of a pulse modulation type receiving apparatus according to a third embodiment of the present invention.
• FIG. 5 A block diagram showing the configuration of a pulse modulation type receiving apparatus according to a fourth embodiment of the present invention.
• FIG. 6 A block diagram showing a configuration of a pulse modulation type receiving apparatus according to a fifth embodiment of the present invention.
• FIG. 7 An explanatory diagram of a signal for RF frame synchronization and a timing signal for RF symbol synchronization in Embodiment 5 of the present invention.
• FIG. 8 A block diagram showing a configuration of a pulse modulation type transmitting apparatus according to a sixth embodiment of the present invention.
• FIG. 9 A block diagram showing a configuration of a pulse modulation type receiving apparatus according to a sixth embodiment of the present invention.
• FIG. 10A Wavelet allocation waveform in a pulse modulation type transmitting apparatus according to a sixth embodiment of the present invention
• FIG. 10B Wavelet allocation waveform in the pulse modulation type transmitting apparatus according to the sixth embodiment of the present invention
• FIG. 11 Various input and output signal waveforms in the pulse modulation type transmitting apparatus according to the sixth embodiment of the present invention
• FIG. 12 A block diagram showing the configuration of a conventional pulse modulation type wireless communication device BEST MODE FOR CARRYING OUT THE INVENTION
• the pulse modulation type transmitting apparatus and the pulse modulation type receiving apparatus according to the present embodiment apply predetermined modulation to the transmission data signal and the frame synchronization signal, and transmit the radio signal upconverted to the radio frequency to the other party of communication.
• a pulse modulation type transmitting apparatus and a pulse modulation type receiving apparatus that receives the radio signal upconverted to the radio frequency and demodulates transmission data.
• FIG. 1 is a block diagram relating to a synchronous operation of a pulse modulation type receiving device in the first embodiment of the present invention.
• FIG. 2 is a block diagram relating to the transmission operation of transmission data and a signal for frame synchronization in the pulse modulation type transmission apparatus in the first embodiment of the present invention.
• pulse modulation type receiving apparatus 100 is connected to two systems of antennas 101a and 101b for receiving radio signals, and receiving section 110a, receiving section 110b, frame synchronization section 140, and symbol synchronization section. And 170.
• the receiving unit 110 a extracts a frequency component including a data signal (hereinafter referred to as an RF data signal) from the wireless signal and amplifies the signal, and the receiving unit 110 b receives the frequency signal from the wireless signal.
• a frequency component having a first template signal for generating a frame synchronization signal (hereinafter, referred to as separately transmitted RF synchronization signal) is extracted and amplified.
• Frame synchronization section 140 receives reception RF data signal 1004 and RF frame synchronization signal 1005 having a first template signal for generating a frame synchronization signal, and receives the received RF data signal.
• a correlation reception data signal 1010 which is a correlation between the signal 1004 and a frame synchronization signal 1009 described later, is output.
• the symbol synchronization unit 170 generates a symbol synchronization signal 1012 generated by the symbol synchronization signal generation unit 172 using the internally generated timing signal 1011 generated based on the correlation reception data signal 1010, and the correlation reception By correlating with the data signal 1010, the decoded data signal 1015 is extracted and output to a signal processing unit in a later stage (not shown).
• Receiving section 110a inputs a radio signal received by antenna 101a to band pass filter 102a, thereby removing noise components other than the frequency band including the RF data signal. Furthermore, by inputting the noise-removed RF data signal to the amplifier 103a, the RF data signal is amplified to a desired power level with low noise and output.
• the receiving unit 110b removes the noise component other than the frequency band including the RF synchronization signal by inputting the radio signal received by the antenna 101b to the band pass filter 102b. Further, by inputting the denoised RF synchronization signal to the amplifier 103b, the separately transmitted RF synchronization signal component is configured to be amplified with low noise to a desired power level and output.
• the frame synchronization unit 140 generates the first template signal timing adjustment unit 160 that generates the first tepla signal 1006 based on the separately transmitted RF frame synchronization signal 1005, and the first template signal 1006.
• the template signal switching unit 142 selects the first template signal 1006 and switches from the first template signal 1006 to the second template signal 1007 according to the synchronization state, and the synchronization output from the template signal switching unit 142 Synchronize the received RF data signal 1 004 on the basis of the template signal 1008 (first template signal 1006 or second template signal 1007)
• a second frame synchronization timing adjustment unit 150 that synchronizes the received RF data signal 1004 with the frame synchronization signal 1009.
• the frame synchronization signal generation unit 141 generates a frame synchronization signal 1009 for communication.
• the first frame synchronization timing adjustment unit 160 causes the first template signal generation unit 161 to generate a carrier of the same frequency as the separately transmitted RF frame synchronization signal and the first template signal, and A modulation signal is generated by modulating the carrier wave with the first template signal 1006, and the output of the correlation determination unit 164 becomes a predetermined value using the correlation unit 162, the low pass filter 163, and the correlation determination unit 164.
• the modulation signal is configured to be synchronized with the separately transmitted RF frame synchronization signal 1005 by feedback control.
• the first template signal generation unit 161 has a template having a rising waveform synchronized with the rising timing of the first template signal included in the separately transmitted RF frame synchronization signal 1005. It is configured to output a 1006 signal.
• the second template signal generation unit 143 is configured to synchronize the internally generated second template signal 1007 with the input first template signal 1006 and output it.
• the template signal switching unit 142 receives the template switching signal 1020 from the frame synchronization correlation determiner 155, switches the first template signal 1006 or the second template signal 1007, and selectively outputs the selected signal. Configure to
• the frame synchronization signal generator 141 receives the first template signal 1006 or the second template signal 1007, generates a carrier wave having the same frequency as the received RF data signal 1004, and the carrier wave is generated by The frame synchronization signal 1009 modulated by the first template signal 1006 or the second template signal 1007 is configured to be output.
• Second frame synchronization timing adjustment section 150 receives frame synchronization signal 1009, and after delaying for a predetermined initial time ⁇ ⁇ in variable delay section 151, amplifier 152 attains a predetermined power level. Using the correlation unit 153, the low pass filter 154, and the frame synchronization correlation detector 155, the synchronization pull-in starts and the output power of the frame synchronization correlation detector 155 is set to the first predetermined value. When reached, a template switching signal 1020 is sent to the template signal switching unit 142. After that, the feedback amount of the variable delay unit 151 is feedback-controlled by the control signal 1013 so that the output of the frame synchronization correlation determiner 155 becomes the second predetermined value, and the frame synchronization signal 1009 is received. Are configured to establish synchronization with the master signal 1004.
• the synchronization state can be divided into two states, and the presence or absence of the RF data pulse constituting the reception RF data signal 1004 is detected, and the synchronization pull-in is performed. There is a pulse capture state for achieving synchronization, and a pulse phase capture state for achieving synchronization of phase levels of wave elements forming an RF data pulse.
• the symbol synchronization unit 170 generates a timing signal 1011 (hereinafter referred to as an internally generated timing signal) based on the correlation reception data signal 1010, and a symbol based on the internally generated timing signal 1011.
• the symbol synchronization signal generation unit 172 that generates the synchronization signal 1012 and the symbol synchronization signal 1012 are synchronized with the correlation reception data signal 1010, and the decoded data signal 1015 is restored and output, and the output is a desired decoded data signal.
• a first symbol synchronization timing adjustment unit 180 which internally performs timing adjustment.
• the timing recovery unit 171 generates an internally generated timing signal 1011 having a rising waveform synchronized with the rising timing of the correlation reception data signal based on the correlation reception data signal 1010 and having a predetermined repetition cycle.
• the symbol synchronization signal generator 172 despreads the correlation reception data signal 1010 based on the internally generated timing signal 1011 to generate a symbol synchronization signal 1012 for recovering the decoded data signal 1015. , Is configured to output.
• the correlation unit 181 After the first symbol synchronization timing adjustment unit 180 delays the input of the symbol synchronization signal 1012 by the variable delay unit 181 by a predetermined initial time nXT (where ⁇ is an integer), the correlation unit The control signal 1014 controls the variable delay unit 181 so that the output of the symbol synchronization correlation determiner 184 has a predetermined value using the low pass filter 182 and the symbol synchronization correlation determiner 184.
• the symbol synchronization signal 1012 is configured to be synchronized with the correlation reception data signal 1010 by performing feedback control of the delay amount of.
• pulse modulation type receiving apparatus 100 receives received RF data signal 1004 from wireless signals received by two systems of antennas 101a and 101b that receive wireless signals, in receiving section 110a.
• the RF frame synchronization signal 1 005 is extracted from the radio signal by the receiver 110 b.
• the extracted received RF data signal 1004 and the RF frame synchronization signal 1 005 are input to the frame synchronization unit 140.
• the first frame synchronization timing adjustment unit 160 receives the RF frame synchronization signal 1005 and outputs a first template signal 1006.
• the template signal switching unit 142 The template signal 1006 is selected and output to the frame synchronization signal generator 141 as the synchronization template signal 1008.
• the frame synchronization signal generation unit 141 receives the synchronization template signal 1008, generates a frame synchronization signal 1009, and outputs the frame synchronization signal 1009 to the second frame synchronization timing adjustment unit 150.
• the second frame synchronization timing adjustment section 150 correlates the received RF data signal 1004 with the frame synchronization signal 1009 while bringing the frame synchronization signal 1009 into synchronization with the received RF data signal 1004.
• a template switching signal 1020 is sent to the template signal switching unit 142.
• the second template signal generation unit 143 synchronizes the internally generated second template signal 1007 with the first template signal 1006.
• the template signal switching unit 142 receives the template switching signal 1020 and switches the input from the first template signal 1006 to the second template signal 1007. Then, the template signal switching unit 142 outputs the second template signal 1007 to the frame synchronization signal generation unit 141 as the synchronization template signal 1008.
• the frame synchronization signal generation unit 141 receives the synchronization template signal 1008, generates a frame synchronization signal 1009, and outputs the frame synchronization signal 1009 to the second frame synchronization timing adjustment unit 150.
• the second frame synchronization timing adjustment section 150 correlates the received RF data signal 1004 with the frame synchronization signal 1009 while bringing the frame synchronization signal 1009 into synchronization with the received RF data signal 1004. Further, the control signal 1013 is output to the variable delay unit 151 until the output of the frame synchronization correlation detector 155 reaches a second predetermined value.
• the pulse modulation type transmitting apparatus 200 performs symbol signal processing for performing predetermined pulse signal string conversion operation (hereinafter referred to as symbolization) on the transmission data signal 2001 and the frame synchronization signal 2002. 210, and one of the outputs of the symbol block 210, the symbol
• the RF data signal transmission unit 220 outputs an RF data signal 2004 which is a radio signal having a data signal obtained by filtering an unnecessary component after performing frequency modulation to a high speed radio frequency and amplification to a predetermined power level.
• an RF synchronization signal transmission unit 230 for outputting an RF frame synchronization signal 2006 which is a wireless signal having a frame synchronization signal obtained by filtering the RF data signal 2004 or the RF frame synchronization signal 2006.
• RF frame synchronization signal 2006 is a wireless signal having a frame synchronization signal obtained by filtering the RF data signal 2004 or the RF frame synchronization signal 2006.
• Symbol part 210 receives transmission data signal 2001 and frame synchronization signal 2002, and symbolizes transmission data signal 2003 and symbolized frame synchronization signal 2005 obtained by symbolizing each signal. Configure to output.
• the RF data signal transmission unit 220 performs predetermined modulation on the symbolized transmission data signal 2033 by the modulation unit 22 la, and then performs frequency conversion to a radio frequency by the frequency conversion unit 222 a. Further, after amplification to a predetermined power level by the amplifier 223a, the band pass filter 224a is configured to output an RF data signal 2004 from which unnecessary components are removed.
• the RF synchronization signal transmission unit 230 performs predetermined modulation on the symbol / frame synchronization signal 2005 by the modulation unit 221b, and then performs frequency conversion to a radio frequency by the frequency conversion unit 222b. Furthermore, after amplification to a predetermined power level by the amplifier 223b, the band pass filter 224b is configured to output an RF frame synchronization signal 2006 from which unnecessary components have been removed.
• the pulse modulation type transmitting apparatus 200 receives a start Z stop instruction signal 2007 for instructing start or stop of the RF synchronization signal transmission unit 230 from a built-in start Z stop instruction signal generation unit (not shown) described later. , Start or stop the RF synchronization signal transmission unit 230; When attempting to start a new communication with the noise modulation type receiver 100, the start Z stop instruction signal The start signal is sent from the generation unit to the RF synchronization signal transmission unit 230.
• the transmission data signal 2001 and the frame synchronization signal 2002 to be transmitted to the pulse modulation type receiving apparatus 100 of the communication partner are input to the symbolization unit 210, Symbolization section 210 applies predetermined symbols to each of transmission data signal 2001 and frame synchronization signal 2002.
• a value (1 or 0) force for each input bit is converted into a plurality of pulse signal trains corresponding to the value and a pattern force configured based on a predetermined rule defined in advance. Output. Also, in symbolization, a symbol of converting a 1-bit input into a pulse signal string of multiple bits, and a symbol of converting a multi-bit input into a pulse signal string of even multiple bits, is performed. It is good.
• a symbolized transmission data signal 2003 obtained by symbolizing transmission data signal 2001 is input to RF data signal transmission section 220, and symbol frame synchronization signal 2005 obtained by symbolizing frame synchronization signal 2002 is an RF synchronization signal.
• Signal transmission unit 230 Signal transmission unit 230.
• the symbolized transmission data signal 2003 input to the RF data signal transmission unit 220 is subjected to predetermined modulation by the modulation unit 221a, and then frequency-converted to a radio frequency by the frequency conversion unit 222a. Further, after being amplified to a predetermined power level by the amplifier 223a, unnecessary components are removed by the band pass filter 224a, and the signal is output to the antenna 201a.
• modulation methods such as OOK (On Off Keying), BPSK (Binary Phase Shift Keying), QPSK (Quadra Phase Shift Keying), and PP M (Pulse Phase Modulation) are used.
• a method of combining a sine wave source and a mixer circuit, and mixing a high frequency carrier signal generated by the sine wave source by the mixer circuit with the output signal of the modulator 22 la, generated by the sine wave source A frequency conversion method such as a method of turning ON / OFF the high frequency carrier signal output by the output signal of the modulator 221a using a switch element or a method of turning ONZOFF the sine wave source itself by the output signal of the modulator 221a is used.
• the RF data signal 2004 output from the RF data signal transmission unit 220 is sent by the antenna 201 a to the pulse modulation type receiving apparatus 100 of the other party of communication via the transmission medium (not shown).
• the symbol synchronization / frame synchronization signal 2055 input to the RF synchronization signal transmission unit 230 is subjected to predetermined modulation by the modulation unit 221 b and then converted to the radio frequency by the frequency conversion unit 222 b. After frequency conversion and amplification to a predetermined power level by the amplifier 223b, unnecessary components are removed by the band pass filter 224b, and the signal is output to the antenna 201b.
• the same modulation method and frequency conversion method as in the RF data signal transmission unit 220 are used. Further, as a modulation method used by each of the modulation unit 221a and the modulation unit 221b, different modulation methods may be used as long as they can be demodulated by the pulse modulation type receiving apparatus 100 on the communication partner side. Furthermore, as long as the frequency conversion method used by each of the frequency conversion unit 222a and the frequency conversion unit 222b is conversion to a predetermined radio frequency, different frequency conversion methods may be used instead of the same method. You can
• the RF frame synchronization signal 2006 output from the RF synchronization signal transmission unit 230 is sent to the pulse modulation type receiving apparatus 100 of the communication partner via the transmission medium (not shown) by the antenna 201 b.
• the operation up to this point is the transmission operation of the transmission data signal 2001 and the frame synchronization signal 2002 in the pulse modulation type transmission apparatus 200 when the RF synchronization signal transmission unit 230 is in the activated state.
• the operation of the pulse modulation type transmitting apparatus 200 when the stop signal output from the start Z stop instruction signal generating unit is applied to the RF synchronization signal transmitting unit 230 will be described.
• the stop signal from the start Z stop instruction signal generating unit is for RF synchronization. It is sent to the signal transmission unit 230. Also, even if it is not a method of issuing a stop signal after receiving a frame synchronization establishment information and a predetermined time has elapsed, frame synchronization is established, and after a predetermined time has elapsed, the pulse modulation type receiving apparatus 100 is stopped.
• the stop signal generation request signal may be sent to the pulse modulation type transmitting apparatus 200, and the stop signal generation request signal may be received to generate a stop signal.
• the power supply start-up Z stop control circuit (not shown) in the RF synchronization signal transmission unit 230 transmits the RF synchronization signal transmission unit 230. Power supply is shut off.
• pulse modulation type receiving apparatus 100 After establishing synchronization using RF frame synchronization signal 1005, synchronization is maintained using frame synchronization signal 10 09 generated using second template signal 1007. ing. Integration of the time lag between the pulse modulation type transmitter side timing and the pulse modulation type receiver side timing due to the prolongation of the elapsed time from the start of communication, pulse modulation type transmitter 200 and pulse modulation type receiver 100 Due to the positional relationship with the network and the time lag due to changes in the communication path, significant desynchronization may occur.
• a force corrected by the second frame synchronization timing adjustment unit 150 inside the frame synchronization unit 140 For example, a time domain in which the second template signal 1007 is “1”.
• synchronization error correction that greatly exceeds synchronization error correction within the device, it is necessary to extend the synchronization correction cycle, and it becomes necessary to set a constant that is contrary to shortening of the synchronization time.
• the start Z stop instruction signal generation unit issues the stop instruction signal, it alternately transmits the start instruction signal and the stop instruction signal toward the RF synchronization signal transmission unit 230 at predetermined time intervals. Do.
• the pulse modulation type receiving apparatus 100 performs synchronization deviation correction using an RF frame synchronization signal (hereinafter referred to as an RF frame synchronization holding signal) transmitted at predetermined time intervals after synchronization is established.
• power supply to the receiving unit 110b of the pulse modulation type receiving apparatus 100 or the first frame synchronization timing adjustment section 160 or both may be stopped, or the pulse modulation type transmitting apparatus
• the power supply of the RF synchronization signal transmitter 230 may be stopped, or both of them may be performed.
• the pulse modulation type receiving apparatus 100 extracts the received RF data signal 1004 from the radio signal sent from the pulse modulation type transmitting apparatus 200 on the communication partner side by the antenna 101a and the receiving unit 110a, and the antenna 101b.
• the RF frame synchronization signal 1005 is extracted by the receiver 110 b.
• frame synchronization section 140 performs frame synchronization with reception RF data signal 1004.
• Signal 1009 is synchronized.
• the RF data pulse train constituting the received RF data signal 1004 may have no pulse signal depending on time.
• a mode for detecting the approximate position of the RF data pulse constituting received received RF data signal 1004, received RF data signal 1004 and frame It is configured in a mode (hereinafter referred to as pulse phase acquisition) in which the phase of the synchronization signal 1009 is made to coincide.
• an RF frame having a template signal which is frame synchronization signal information synchronized with an RF data pulse which is data signal information in a pulse capturing process is used.
• the frame synchronization signal generation unit 141 generates the frame synchronization signal based on the first template signal 1006 from the first frame synchronization timing adjustment unit 160. Synchronize frame synchronization signal 1009 with received RF data signal 1004. At this time, since the phase relationship between the RF data pulse and the first template signal 1006 that constitutes the frame synchronization signal 1009 is the same timing, the RF data pulse that constitutes the RF data signal and the RF frame synchronization signal 1005 have. The phase relationship with the template signal is also matched.
• the frame synchronization signal generation unit 160 since the first template signal 1006 output from the first frame synchronization timing adjustment unit 160 has the same phase relationship as the template signal of the RF frame synchronization signal 1005, the frame synchronization signal generation unit The frame synchronization signal 1009 generated at 141 is also in phase with the RF data pulses that make up the received RF data signal 1004. As a result, the first power of the synchronization establishment process is It becomes possible to realize the capture of the light.
• correlation output is obtained from the beginning of the synchronization establishment process if the reception RF data signal 1004 and the frame synchronization signal 1009 are multiplied by the correlation unit 153.
• the correlation judgment unit for frame synchronization 155 judges the correlation between the received RF data signal 1004 and the signal 1009 for frame synchronization, and the variable delay unit 151 controls the control signal 1013 until the correlation output becomes a first predetermined value.
• the carrier wave of the RF data signal at the rise of the RF data pulse constituting the reception RF data signal 1004 and the signal for frame synchronization at the rise of the template signal for synchronization constituting the signal 1009 for frame synchronization It is desirable that the phase relationship with the carrier wave of each carrier should be matched, that is, the same timing, but the correlation output can be obtained even if the phase relationship of each carrier level is not matched. It is controlled to match the phase relationship of the carrier level.
• the phase relationship with the frame synchronization signal carrier is designed, feedback control is not performed, and the delay amount of the variable delay unit 151 is set to 0 (zero) to perform pulse acquisition and pulse phase acquisition. It can be realized simultaneously. In this case, the time required to establish synchronization is almost unnecessary, and since the correlation reception data signal 1010 is also obtained at the start of frame synchronization establishment operation, there is no need to transmit extra data for frame synchronization establishment, and further High speed data communication is possible.
• the delay amount is described as 0 (zero)
• the template signal switching unit 142, the variable delay unit 151, the amplifier 152, and a wiring (not shown) up to the correlation unit 153 have this.
• the inherent delay amount is appropriately corrected.
• the inherent delay amounts possessed by the antennas 101a and 101b, the bandpass filters 102a and 102b, and the low noise amplifiers 103a and 103b are appropriately corrected as well.
• a template used to generate the frame synchronization signal 1009 The signal is switched from the first template signal 1006 generated by the first frame synchronization timing adjustment unit 160 to the second template signal 1007 generated by the second template signal generation unit 143.
• synchronization establishment which is timing alignment between the template signal 1006 and the second template signal 1007.
• This synchronization establishment operation uses a correlation unit (not shown) in the second template signal generation unit 143, a low pass filter, a correlation determination unit, a variable delay unit, etc., and uses the first or second frame synchronization timing. It is performed by performing the same operation as the operation used by the adjustment units 160 and 150.
• the synchronization holding state is also referred to the first template signal 1006 after synchronization is established or at a predetermined time before the output of the template signal 1006 is stopped after the synchronization is established. Without referring to the first template signal 1006, it shifts to a self-synchronization holding state in which the synchronization establishment state is held.
• the first frame synchronization timing adjustment unit 160 It is possible to maintain the first state of synchronization establishment even if the operation of is stopped.
• an RF frame synchronization holding signal input detection circuit (not shown) for performing synchronization correction using an RF frame synchronization holding signal input detection circuit. It is detected that the frame synchronization holding signal is the first template signal generated by the input. After that, the self-synchronization holding state is stopped, and the second template signal 1007 is resynchronized with the first template signal 1006.
• the self-synchronization holding state and the resynchronization state are alternately repeated according to the input of the synchronization error correction RF frame synchronization holding signal.
• the template signal switching unit 142 switches the input from the first template signal 1006 to the second template signal 1007 and outputs it as a synchronization template signal 1008 to the frame synchronization signal generation unit 141.
• transition from frame synchronization using RF frame synchronization signal 1005 to frame synchronization using second template signal 1007 is performed, and second template signal 1007 is used.
• the used frame synchronization holding state is established.
• the decoded data signal 1015 is restored in the symbol synchronization unit 170 based on the correlation reception data signal 1010 output from the frame synchronization unit 140.
• pulse modulation type transmission apparatus 200 one or more bits of the transmission data signal in symbol conversion section 210 are converted and output into a plurality of pulse signal trains having pattern powers configured based on a predetermined rule. ing.
• an operation performed by the symbolization unit 210 is a diffusion coding process. Further, as an operation performed by the symbol synchronization unit 170, there is a despreading coding process.
• symbol code ⁇ is not a necessary operation, it is one of the methods to realize multiplexing in pulse communication as well as CDMA communication using a continuous wave.
• the correlation reception data signal 1010 input to the symbol synchronization unit 170 is divided into two by a distributor (not shown), and one is input to the first symbol synchronization timing adjustment unit 180 and the other is input to the timing recovery unit 171. .
• the second template signal generation unit 143 of the frame synchronization unit 140 When the correlation reception data signal 1010 is input to the timing recovery unit 171, the second template signal generation unit 143 of the frame synchronization unit 140 generates a second template signal based on the correlation reception data signal 1010. By substantially the same operation as described in the operation, an internally generated timing signal 1011 is generated in which pulses occur at predetermined time intervals.
• the first and second frame synchronization timing adjustment units 160 and 150 are used by using a correlation unit (not shown) inside the timing recovery unit 171, a low pass filter, a correlation determination unit, a variable delay unit, and the like.
• the internally generated timing signal 1011 synchronized with the correlated reception data signal 1010 is generated and output to the symbol synchronization signal generation unit 172.
• BPSK is used as the modulation method
• the data sequence of correlated reception data signal 1010 is continuous at a constant interval, so that only the amplitude information is used to generate internally generated timing signal 1011. can do.
• OOK modulation or PPM modulation is used, although the data strings are not at fixed intervals, it is possible to generate an internally generated timing signal 1011 for establishing symbol synchronization with any data string. .
• the symbol synchronization signal generation unit 172 receives the internally generated timing signal 1011 and generates a symbol synchronization signal 1012 having a plurality of pulse trains for recovering the decoded data signal 1015, and performs the first symbol synchronization. It is sent to the timing adjustment unit 180.
• first symbol synchronization timing adjustment section 180 correlation section 182 multiplies input correlation reception data signal 1010 and symbol synchronization signal 1012 by correlation section 182 to obtain a decoded data signal from the other end of the communication. And outputs a decoded data signal 1015.
• the timing of the symbol synchronization signal 1012 and that of the correlation reception data signal 1010 are deviated, a state in which an incorrect time slot is at the head of a symbol in the correlation reception data signal pulse train due to this timing deviation. Therefore, symbol synchronization is realized by changing the delay time of the variable delay unit 181.
• the delay time is changed by the symbol synchronization correlation determiner 184 from the symbol synchronization correlation determiner 184 to the variable delay unit 181 until the correlation value reaches a predetermined value. It is realized by sending out 1014.
• the variable delay unit 181 changes the delay time based on the control signal 1014 for changing the delay amount.
• the amount of change is changed quantumally with the time set T as the step width. However, if the step width is increased or decreased continuously one by one, the number of steps increased or decreased according to the amount of change. I can change it.
• the transmission data signal 2001 and the frame synchronization signal are transmitted to the pulse modulation type transmitting apparatus 200.
• An RF data signal transmission unit 220 and an RF synchronization signal transmission unit 230 for separately transmitting 2002 and 2002 are provided, and a frame synchronization unit 140 of the pulse modulation type receiving apparatus 100 is further transmitted with a signal for RF frame synchronization.
• a first frame synchronization timing adjustment unit 160 that generates a first template signal 1006 generated based on 1005, and a template that generates a second template signal 1007 that is synchronized to the first template signal 1006.
• a template signal switching unit 142 that selects one of the first template signal 1006 and the second template signal 1007 according to the synchronization state and switches and outputs it as a synchronization template signal 1008, and the reception RF
• a frame synchronization signal generator 141 which receives a template signal 1008 for synchronization synchronized with an RF data pulse forming the data signal 1004 and generates a signal 1009 for frame synchronization, a received RF data signal 1004 and a signal 1009 for frame synchronization
• a second frame synchronization timing adjustment unit 150 that generates and outputs a correlation reception data signal 1010 from the signal acquisition unit, and the RF frame synchronization signal 1005 is used for pulse capture or pulse phase capture at initial synchronization establishment at the start of communication.
• Frame synchronization is performed by the first template signal 1006 generated based on the second template signal after synchronization is established.
• frame synchronization is performed using a frame synchronization signal generated internally without using the RF frame synchronization signal 1005 separately transmitted, Since synchronization can be established in a short time, communication speed can be increased.
• the second template signal is synchronized with the first template signal 1006, and the first template signal 1006 to the second template signal 1007 are held as synchronization after synchronization establishment.
• the frequency band used for RF frame synchronization signal transmission is also for RF transmission data signal transmission. Since it can be used, a pulse modulation type transmitter, pulse modulation type receiver and system capable of further high-speed data transmission can be realized.
• the frame synchronization unit 140 of the above embodiment uses the first template signal 1006 generated from the RF frame synchronization signal 1005 separately transmitted to establish frame synchronization, and the second synchronization holding after synchronization establishment. Shows a configuration that uses the template signal 1007 of The received RF data signal 1004 may be used as a second template signal for later synchronization. Furthermore, synchronization may be established not only by synchronization but also as a configuration in which the received RF data signal 1004 is used as a first template signal generated from the RF frame synchronization signal 1005 sent separately.
• the information to be transmitted separately is described as the frame synchronization timing indicating the pulse position and phase, and the symbol synchronization timing indicating the position of the code string
• Information may be sent separately.
• a device capable of receiving a signal including authentication information sent separately receives a request for transmission from another device and limits the other party of communication.
• data for authentication may be added to either the RF frame synchronization signal or the RF symbol synchronization timing signal, or may be separately transmitted as a new signal.
• the data signal, the frame synchronization timing signal, and the symbol synchronization timing signal may change the data rate. This makes it possible to narrow the occupied band of the low rate signal and reduce the frequency band used by changing the data rate of each signal.
• sparse synchronization is performed in a low-rate communication system or communication system.
• power consumption of the synchronous circuit can be reduced, and by performing sparse synchronization at fixed time intervals, accuracy can be reduced. The time from the start of high synchronization to the establishment of synchronization can be shortened.
• FIG. 1 A block configuration of the pulse modulation type receiving apparatus according to the embodiment 2 of the present invention is shown in FIG.
• FIG. 3 uses the first template signal 1006 generated from the RF frame synchronization signal 1005 sent separately to establish frame synchronization, and the reception RF data signal 1 004 has a variable delay unit 343 for maintaining synchronization after establishment of synchronization.
• the configuration of the pulse modulation type receiving apparatus 100 shown in FIG. 1 differs from that of FIG. 1 in that the second template signal generation unit 143 and the template signal switching unit 142 are not provided, and a frame synchronization signal switching unit 342 and a variable delay unit 343.
• the data signal 1004 is delayed by the variable delay unit 343 for a predetermined time T and then input to the frame synchronization signal switching unit 342.
• the difference from the operation of the frame synchronization unit 140 is as follows.
• frame synchronization signal switching unit 342 uses frame signal 1006 to perform frame synchronization.
• the frame synchronization signal 1009 generated by the signal generation unit 141 is selected and output to the second frame synchronization timing adjustment unit 150.
• the second frame synchronization timing adjustment unit 150 synchronizes the frame synchronization signal 1009 output from the frame synchronization signal switching unit 342 with the reception RF data signal 1004 while receiving the reception RF data signal 1004. Correlation with the frame synchronization signal 1009 output from the frame synchronization signal switching unit 342 to determine the frame synchronization correlation.
• a frame synchronization signal switching signal 3020 is sent to the frame synchronization signal switching unit 342.
• the frame synchronization signal switching unit 342 receives the frame synchronization signal switching signal 3020, switches the input to the delayed reception RF data signal 3010 from the template signal 1006, and transmits the second frame synchronization timing adjustment unit 150. Output.
• the second frame synchronization timing adjustment section 150 correlates the reception RF data signal 1004 with the delay reception RF data signal 3010 while bringing the delay reception RF data signal 3010 into synchronization with the reception RF data signal 1004.
• the control signal 1013 is output to the variable delay unit 151 until the output of the correlation detector for frame synchronization 155 reaches a second predetermined value.
• the output of the correlation detector for frame synchronization 155 reaches a second predetermined value, synchronization of the delayed reception RF data signal 3010 with respect to the reception RF data signal 1004 is established, and the predetermined correlation reception data signal 1010 is a frame. It is output from the synchronization correlation determination unit 155.
• received RF data signal 1004 is branched into two, one of which is a variable delay unit.
• the delayed reception RF data signal 3010 delayed by a predetermined time T according to H. 343 is used to perform the delay detection for detecting the correlation reception data signal 1010.
• the above is the difference from the operation of the frame synchronization unit 140.
• the second template signal generation unit 143 is generated inside the frame synchronization unit 340. As the circuit configuration is simplified because it is not necessary to have the power consumption can be reduced.
• the signal levels of amplifiers or the like may be used depending on the elements used for multiplication processing and correlation processing. Needless to say, to make adjustments.
• FIG. 4 shows the block configuration of the pulse modulation type receiving device in mode 3.
• FIG. 4 is a block diagram of a pulse modulation type receiving apparatus having a frame synchronization unit 440 which uses received RF data signal 1004 in synchronization pull-in and establishment of synchronization.
• the difference from the pulse modulation type receiver shown in FIG. 3 is that it is not connected to the antenna 101b and does not have the receiver 110b, and an RF data signal is branched into three and input to the frame synchronization unit 440.
• the point is that the received RF data signal 1004 which is not the frame synchronization signal 1005 is input to the correlation unit 162 of the first frame synchronization timing adjustment unit 160.
• the operation of the frame synchronization unit 340 is different from that described below in the following points.
• the delayed reception RF data signal 3010 is selected by the frame synchronization signal switching unit 342, and the second frame synchronization timing adjustment unit 150 is selected.
• the second frame synchronization timing adjustment unit 150 synchronizes the reception RF data signal 3010 output from the signal synchronization signal switching unit 342 with the reception RF data signal 1004 while synchronizing the reception RF data signal 1004.
• the signal 1004 is correlated with the delayed received RF data signal 3010 output from the frame synchronization signal switching unit 342 and the output of the frame synchronization correlation detector 155 reaches a first predetermined value, frame synchronization is performed.
• a frame synchronization signal switching signal 3020 is sent to the signal switching unit 342.
• the frame synchronization signal switching unit 342 receives the frame synchronization signal switching signal 3020, switches the input from the delayed reception RF data signal 3010 to the frame synchronization signal 4009, and adjusts the second frame synchronization timing. Output to section 150.
• Second frame synchronization timing adjustment section 150 correlates reception RF data signal 1004 with frame synchronization signal 4009 while establishing synchronization of frame synchronization signal 4009 with reception RF data signal 1004.
• the control signal 1013 is output to the variable delay unit 151 until the output of the correlation detector for frame synchronization 155 reaches a second predetermined value.
• the output of the correlation detector for frame synchronization 155 reaches a second predetermined value, synchronization of the delayed reception RF data signal 3010 with respect to the reception RF data signal 1004 is established, and the predetermined correlation reception data signal 1010 is a frame. It is output from the synchronization correlation determination unit 155.
• the reception RF data signal 1004 is branched into three, and when drawing in frame synchronization, it takes three minutes.
• a variable delay unit 343 performs delayed detection of the correlated received data signal 1010 using one of the delayed signals by the delayed received RF data signal 3010 delayed by a predetermined time T.
• the frame synchronization signal 4009 generated by the frame synchronization signal generator 141 based on the template signal 1006 generated using another received RF data signal 1004 out of the three branches is used. Using this, synchronous detection is performed to detect the correlation received data signal 1010.
• the above is the difference from the operation of the frame synchronization unit 340.
• delay detection is performed to detect the correlation reception data signal 1010 by delaying one of the three branches of the reception RF data signal 1004 for a predetermined time T.
• the first template signal generation unit 161 generates a first template signal 1006 in which 1 and 0 are alternately continuous.
• the frame synchronization signal switching unit 342 is synchronized with the rising waveform of the RF data pulse forming the reception RF data signal 1004, and then receives the reception RF data signal 1004 from the frame synchronization signal generation unit 141. It switches to the frame synchronization signal 4009 and outputs it to the second frame synchronization timing adjustment unit 150.
• the RF data pulses that the received RF data signal 1004 has are not continuous with 1s and 0s alternately.
• the sensitivity in the correlation detector 164 is reduced.
• a pulse modulation type transmitting apparatus and a pulse modulation type receiving apparatus according to a fourth embodiment of the present invention will be described.
• the difference from the first embodiment is that the pulse modulation type receiving apparatus is different, and the pulse modulation type transmitting apparatus is the same as the first embodiment.
• the block configuration of a pulse modulation type receiving apparatus according to the fourth embodiment of the present invention is shown in FIG.
• the difference from Embodiment 1 is that, in addition to the separately transmitted RF frame synchronization signal 1005 used in the frame synchronization unit 140, a signal itself of a format necessary as a timing signal for symbol synchronization is used. , And at another radio frequency (hereinafter referred to as an RF timing signal).
• timing signal there are a format in which the signal is generated only at the start of the symbol, a format in which the signal is generated at the timing of a plurality of bits in the symbol, and the like.
• pulse modulation type reception apparatus 500 transmits to symbol synchronization section 570 a baseband timing signal from RF symbol synchronization timing signal 5006 transmitted separately.
• a second symbol synchronization timing adjustment unit 560 that detects the first timing signal and performs amplitude addition, and a timing signal 5008 synchronized with the RF symbol synchronization timing signal 5006 (hereinafter referred to as the second And a timing signal switching unit 573 for switching and outputting one of the second timing signal 5008 and the first timing signal 5007.
• the second symbol synchronization timing adjustment unit 560 detects a baseband timing signal from the RF symbol synchronization timing signal 5006 in the detection unit 501 and divides one of the detection signals into two for a predetermined time m
• the first timing signal 5007 having a predetermined amplitude or more is output by being delayed by XT and added to the other.
• the clock recovery unit 571 generates a timing signal internally generated by an internal template signal generation unit, a variable delay unit, a correlation unit, a low pass filter, a correlation determination unit, etc. (not shown). It is configured to synchronize with the RF symbol synchronization timing signal 5006 and output it.
• Timing signal switching unit 573 synchronizes second timing signal 5008 with first timing signal 5007, receives symbol synchronization signal switching signal 5020 from symbol synchronization correlation determiner 184, and It is configured to switch from the timing signal 5007 of 1 to the second timing signal 5008 and output it.
• the first timing signal 5007 may be switched to the second timing signal 5008 after a predetermined time has elapsed and may be output.
• symbol synchronization unit 570 can establish symbol synchronization using first timing signal 5007. First, after the RF symbol synchronization timing signal 5006 is extracted from the radio signal by the antenna 101b and the reception unit 110b, the signal is input to the second symbol synchronization timing adjustment unit 560.
• the detection unit 501 detects a baseband timing signal from the RF symbol synchronization timing signal 5006, and one of the two detection signals is branched by the variable delay unit 503.
• the signal is delayed by a predetermined time m XT, added to the other detection signal by the addition / reset circuit unit 502, reset after addition a predetermined number of times, reset, and added an appropriate number of signals, and an external timing signal 5007 is output.
• m is an integer representing the number of frames constituting one symbol
• T represents a time of one symbol length.
• the external timing signal 5007 is selected by the timing signal switching unit 573, and is output to the symbol synchronization signal generation unit 172.
• the subsequent operation of generating a symbol synchronization signal based on the first timing signal input to the symbol synchronization signal generation unit 172 is the same as that of the first embodiment.
• the first timing signal 5007 is branched into two, one of which is input to the clock recovery unit 571.
• the timing signal generated by the internal template signal generation unit (not shown) is initially delayed by the variable delay unit for a predetermined time, and then correlated with the external timing signal 5007 by the correlation unit. Pass through the low pass filter After that, the amount of delay of the variable delay unit is feedback-controlled until the correlation output reaches a predetermined value by the correlation determination unit. When the correlation output reaches a predetermined value, the second timing signal 5008 generated inside the clock recovery unit 571 is synchronized with the first timing signal 5007.
• the timing signal switching unit 573 synchronizes the second timing signal 5008 with the first timing signal 5007, and after a predetermined time passes, the first timing signal 5007 to the second timing signal 5008 are synchronized. , And output to the symbol synchronization signal generator 172.
• the RF symbol synchronization timing signal 5006 is stopped after a predetermined time, and the RF timing signal for symbol synchronization (hereinafter referred to as a symbol synchronization holding timing signal) is transmitted at predetermined time intervals.
• a symbol synchronization holding timing signal the RF timing signal for symbol synchronization
• the RF of the separate transmission to the pulse modulation type transmitting apparatus 200 of the first embodiment is transmitted.
• the RF symbol synchronization timing signal is further transmitted separately, and the pulse modulation type receiving apparatus 100 according to the first embodiment further includes a first timing signal 5007 for the RF symbol synchronization timing signal.
• the second symbol synchronization timing adjustment unit 560 to detect and the first timing signal 5007 for establishing or maintaining symbol synchronization, symbol synchronization is established, and the symbol synchronization signal from the symbol synchronization correlation determination unit 184 By providing the timing switching portion 573 for switching from the first timing signal 5007 to the second timing signal 5008 in response to the switching signal 5020, Together it can be shortened synchronization establishment time in-time synchronization, further attained also shorten your Keru synchronization establishment time in the synchronization symbol.
• the symbol synchronization may be established and switched from the external timing signal 5007 to the internal timing signal 5008 after a predetermined time has elapsed.
• the signal for RF synchronization on the side of pulse modulation type transmitting apparatus 200 is used.
• the RF frame synchronization signal on the pulse modulation type transmission device 200 side is also performed during symbol synchronization holding.
• the transmission with the transmission of the RF symbol synchronization timing signal can be stopped, and the operation of the low noise amplifier 103b on the pulse modulation type receiving device 500 side and the second symbol synchronization timing adjustment unit 560 can be stopped. Power consumption can be further reduced by reducing the number of operation circuits in the pulse modulation type transmitting apparatus 200 and the pulse modulation type receiving apparatus 500.
• the RF frame synchronization signal and the RF Since the frequency band used for transmission with the symbol synchronization timing signal can be used for transmission of the transmission data signal, it is possible to realize a pulse modulation type transmission device and pulse modulation type reception device capable of further high-speed data transmission. .
• FIG. 1 A block configuration of the pulse modulation type receiving apparatus according to the fifth embodiment of the present invention is shown in FIG.
• FIG. 6 differs from the configuration of Embodiment 4 in the RF frame synchronization signal 1005 and the RF symbol synchronization timing signal 50 separately transmitted to the pulse modulation type transmitter.
• the RF frame synchronization signal 1005 and the RF symbol synchronization timing signal 5006 are extracted by separate radio reception systems and output. That is the point.
• pulse modulation type receiving apparatus 600 is further connected to antenna 601, and has receiving section 110c.
• a radio signal to RF signal can be generated. After extracting the timing signal 5006 for low synchronization and amplifying it with low noise to a predetermined power level, and then outputting the extracted signal to the second timing adjustment circuit 560 for symbol synchronization. It is.
• FIG. 7 shows RF frame synchronization signal 1005 and RF symbol synchronization timing signal 5006 which are separately transmitted.
• the RF frame synchronization signal 1005 used at the time of synchronization establishment for performing pulse capture and pulse phase capture has a pulse width of an RF data pulse forming an RF data signal at time tl to tn separated by a constant time T. It consists of sine waves that are excited intermittently for the same time length tel.
• the pulse width tel of the transmitting and receiving pulse is shorter than the time interval T.
• the symbol synchronization signal generation unit 172 generates a symbol synchronization signal based on the signal start time tl of the RF symbol synchronization timing signal 5006 used for symbol synchronization. Therefore, it is only necessary to excite the sine wave for a predetermined time only during the time t1 which is not necessary to intermittently excite the sine wave at all the times tl to tn. Also, the excitation time may be longer than tel. In FIG. 7, excitation is performed for time T only.
• a second narrowband frequency channel different from that for initial frame synchronization establishment is assigned to the separately transmitted RF symbol synchronization timing signal 5006 used for symbol synchronization.
• an RF frame synchronization signal By providing a configuration for transmitting and receiving 1005 and RF symbol synchronization timing signal 5006 at different radio frequencies, the first frame synchronization timing adjustment section and the first frame synchronization timing adjustment section and the second frame synchronization timing signal 5006 can be compared The second symbol synchronization timing adjustment units 160 and 560 remove the influence of the mutual signal components.
• Embodiment 4 in which the frame synchronization establishment time and symbol synchronization establishment time can be shortened, more stable frame synchronization signal and symbol synchronization timing signal can be extracted. Furthermore, it is possible to obtain a correlated reception data signal or a recovered data signal which is stable with less jitter.
• Embodiment 6 Next, a pulse modulation type transmitting apparatus and pulse modulation type receiving apparatus according to a sixth embodiment of the present invention will be described.
• the difference from the fifth embodiment is that the pulse modulation type receiving apparatus and the pulse modulation type transmitting apparatus are different !.
• the block configuration of the pulse modulation type transmitting apparatus according to the sixth embodiment of the present invention is shown in FIG. 8, and the block configuration of the pulse modulation type receiving apparatus is shown in FIG.
• pulse modulation type transmission apparatus 800 in addition to the configuration of pulse modulation type transmission apparatus 200, pulse modulation type transmission apparatus 800 includes waveform selection section 81 la, 8 between modulation sections 221a and 221b and frequency conversion sections 222a and 222b. It is configured to have l ib.
• pulse modulation type reception apparatus 900 has timing generation section 571 for generating the second timing in symbol synchronization section 570 of pulse modulation type reception apparatus 600, and timing switching section 573. Also, the second symbol synchronization timing adjustment unit does not have the detection unit 501 and the addition / reset circuit unit 502, and has the correlation unit 901, the low pass filter 902, and the correlation determination unit 903. It becomes the composition.
• transmission data signal 2001 and frame synchronization signal 2002 are symbolized by symbolization section 210, and after predetermined modulation is performed by modulation sections 221a and 221b, waveform selection section 811a, Wavelets having a predetermined waveform are assigned at 8 l ib, frequency-converted by frequency conversion units 222 a and 222 b, and transmitted.
• the symbol synchronization timing signal 8003 is symbolized by the symbolization unit 210, subjected to predetermined modulation by the modulation units 221a and 221b, and then transmitted by the waveform selection unit 81 lb.
• a wavelet having a waveform different from that of the frame synchronization signal is assigned.
• FIGS. 10A and 10B show the waveforms of the wavelets used for the transmission data signal 2001 or the signal 2002 for frame synchronization and the timing signal 8003 for symbol synchronization.
• Figure 10A is the first derivative of the Gaussian impulse waveform
• FIG. 10B shows the second derivative of the Gaussian impulse waveform, where the abscissa represents time and the ordinate represents amplitude.
• the waveforms in FIG. 10A and FIG. 10B are in a temporally orthogonal relationship with each other, and are waveforms that can be separated on the pulse modulation type receiver side.
• FIGS. 10A and 10B use the first-order derivative waveform of the Gaussian impulse waveform of FIG. 10A for transmission data signal 2001 and frame synchronization signal 2002, and uses symbol synchronization timing signal 8003 for transmission synchronization. It is not necessary to simply assign the second-order differential waveform of the Gaussian impulse waveform shown in FIG. 10B. Also, the waveform of the wavelet used is only an example, and is not limited to the waveforms shown in FIGS. 10A and 10B as long as they are orthogonal to each other in time.
• the output signals from transmit data signal 2001 and waveform selectors 811 a and 8 l ib of symbol synchronization timing signal 8003 are respectively selected as transmit data 8005 for waveform selection and signal 8006 for waveform selection symbol synchronization.
• the output signals of the conversion units 222a and 222b are RF transmission data 8007 and RF symbol synchronization signal 8008, respectively
• FIG. 11 shows the waveforms and relationships of the input and output signals.
• the symbol synchronization timing signal 8003 has a length and a pulse width.
• pulse modulation type reception apparatus 900 extracts RF symbol synchronization timing signal 5006 from a radio signal using antenna 601, band pass type filter 602 of reception section 110c, and low noise amplifier 603. After amplification with low noise to a predetermined power level, the extracted signal is output to the second symbol synchronization timing adjustment unit 960. At this time, the RF frame synchronization signal 1005 having different wavelets is removed by the second symbol synchronization timing adjustment unit 960 even if the carrier frequency is the same as the frequency band to be transmitted.
• Second symbol synchronization timing adjustment section 960 splits the input RF symbol synchronization timing signal into two, and delays one signal by time m XT by delay section 503 (however, m Is an integer), and the other signal is input to the correlation unit 901 to perform differential detection.
• the correlation determiner 903 changes the m value of the delay unit 503 until the correlation value becomes a predetermined value. When the correlation value reaches a predetermined value, the timing signal required for desired symbol synchronization is correlated. It is outputted from the judgment unit 903.
• the configuration of the pulse modulation type receiving apparatus of the fifth embodiment is slightly modified. Further, by providing a configuration in which different wavelets are applied to the RF frame synchronization signal 8008 and the RF symbol synchronization timing signal 8009 on the pulse modulation type transmitting apparatus 800 side, the RF frame synchronization signal 8008 and the RF symbol synchronization timing signal The 8009 can be sent in the same frequency band.
• the RF frame synchronization signal 1005 and the RF symbol synchronization timing signal 5006 can be easily separated at the pulse modulation type receiving apparatus 900 side, different wavelets are not applied, and the same signal is generated. Since the first frame synchronization timing adjustment unit and the second symbol synchronization timing adjustment units 160 and 960 remove the influence of each other's signal components as compared to the case of receiving on a radio frequency, the frame is eliminated. According to the effect of the fifth embodiment that the synchronization establishment time can be shortened and the symbol synchronization establishment time can be shortened, more stable frame synchronization signal and symbol synchronization timing signal can be extracted. In addition, it is possible to obtain a correlated reception data signal or a restored data signal which is stable with less jitter.
• the pulse modulation type transmitting apparatus, pulse modulation type receiving apparatus and system according to the present invention can shorten the time required for establishing synchronization and can transmit and receive data more quickly than the start of communication,
• the power consumption of the synchronization unit can be reduced even with a configuration having a plurality of reception systems, and AV devices and personal computers can be wirelessly connected to each other. Therefore, the present invention is useful as a data communication apparatus or a UWB wireless apparatus using a pulse-like modulation signal to form a seamless network.

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• 2006
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