WO1997035397A1 - Systeme de radiocommunication a sauts de frequence et procede d'acquisition synchrone - Google Patents

Systeme de radiocommunication a sauts de frequence et procede d'acquisition synchrone Download PDF

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Publication number
WO1997035397A1
WO1997035397A1 PCT/JP1996/000679 JP9600679W WO9735397A1 WO 1997035397 A1 WO1997035397 A1 WO 1997035397A1 JP 9600679 W JP9600679 W JP 9600679W WO 9735397 A1 WO9735397 A1 WO 9735397A1
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WO
WIPO (PCT)
Prior art keywords
frequency
hopping
sequence
hobbing
carrier
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PCT/JP1996/000679
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English (en)
Japanese (ja)
Inventor
Yasuo Ogoshi
Ritsuko Sasae
Masahiro Ito
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Hitachi, Ltd.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Hitachi, Ltd. filed Critical Hitachi, Ltd.
Priority to PCT/JP1996/000679 priority Critical patent/WO1997035397A1/fr
Publication of WO1997035397A1 publication Critical patent/WO1997035397A1/fr

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J13/00Code division multiplex systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B1/00Details 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
    • H04B1/69Spread spectrum techniques
    • H04B1/713Spread spectrum techniques using frequency hopping

Definitions

  • the present invention relates to a wireless communication system, and more particularly, to a frequency hobbing wireless communication system and a synchronization acquisition method in which a communication device on a transmission side and a communication device on a reception side communicate while hopping a carrier frequency according to a predetermined hobbing sequence.
  • the spread spectrum communication method is a communication method in which a transmission signal is spread over a frequency band wider than the spanned bandwidth and transmitted, and is excellent in interference resistance and confidentiality.
  • the spectrum is spread by replacing each symbol (bit) of the transmission signal with a spreading code consisting of a plurality of chips.
  • the transmitting and detecting frequencies are synchronized with each other and hopped according to the same hopping sequence (hopping pattern) as the transmitting communication device and the receiving communication device.
  • the hopping sequence of the carrier frequency used at this time includes one having a relatively short repetition period and one having a long repetition period in order to improve confidentiality.
  • the receiving device specifies which carrier frequency currently used by the transmitting device is in the hobbing sequence, and determines the detection frequency. Synchronous acquisition technology that synchronizes the hopping timing with the transmitting side is important. As one of the conventional hopping synchronization methods, for example, as shown in FIG.
  • the receiving device is a hopping sequence of F (1), F (2), ising F (j), F (j + 1), ising F (n). And the receiving device stops the frequency hopping operation and monitors the detection output while maintaining the detection frequency at a specific frequency (hereinafter referred to as a standby frequency) f (w), and detects the detection output ( From the state change of the carrier sense output), it is detected that the carrier frequency of the received signal coincides with the standby frequency f (w) (in FIG. 1, the hopping frequency becomes F (j)).
  • a standby frequency hereinafter referred to as a standby frequency
  • a standby hopping synchronization scheme J in which a hopping operation is started, and it is confirmed that the transmission and reception side frequencies are continuously the same for a predetermined number of hops, and the state is shifted to a synchronization holding state. .
  • Figure 2 shows n types of frequencies that can be hopped, and carrier frequencies are successively changed by periodically repeating a hopping sequence consisting of n hops from F (l) to F (n). A relatively short-period frequency hopping pattern is shown.
  • each frequency is used only once per cycle of the hopping sequence. Therefore, if the above-mentioned standby synchronization acquisition method is adopted in a communication system using a short-period hopping pattern, for example, the transmission side device ties immediately after the carrier frequency hops to the frequency next to the reception side standby frequency f (w).
  • the receiving device starts the synchronization acquisition operation by mining, it takes one cycle (n hops) of the hopping sequence before the receiver succeeds in carrier sensing.
  • the standby frequency for example, when the reception of radio waves is disturbed by noise, Otherwise, there is a problem that the chance of carrier sensation does not come around.
  • the maximum value of the required carrier sense time is proportional to the hopping sequence length (the number of hops n for one cycle).
  • the hop period T h of the carrier frequency on the transmitting side is used.
  • the receiver S performs a high-speed hobbing operation on all frequencies of the hobbing sequence to find the carrier frequency of the received signal.
  • the hopping interpulse T h 'on the receiving side becomes extremely short due to the high hopping speed on the transmitting side, the switching operation of the output frequency of the frequency synthesizer is switched.
  • the high-speed search method uses a special frequency at which the carrier frequency on the transmitting side is switched at a low speed. It is effective in hopping communication.
  • An object of the present invention is to provide a frequency hobbing wireless communication system and a carrier sense method capable of capturing a hobbing frequency in a short time.
  • Another object of the present invention is to provide a frequency hobbing operation capable of synchronizing the frequency hobbing operation on the receiving side with the transmitting side within an allowable time shorter than one cycle of the hobbing sequence. And a synchronization acquisition method.
  • Still another object of the present invention is to provide a transmission apparatus in which synchronization control information is transmitted within a predetermined number of hops prior to data transmission, and a reception apparatus which acquires synchronization of a hobbing frequency within the synchronization period. It is an object of the present invention to provide a frequency hobbing radio communication system which is completed and thereafter performs data reception, and a synchronization acquisition method suitable for the same.
  • Still another object of the present invention is to provide a radio communication system in which a transmitting apparatus periodically hops a carrier frequency in accordance with a predetermined hobbing sequence using n types of frequencies once each period. 1 cycle of
  • An object of the present invention is to provide a synchronization acquisition device g and a synchronization acquisition method capable of achieving synchronization acquisition during a predetermined number of frequency hobbing periods ⁇ much shorter than (n hops). Disclosure of the invention
  • a method for synchronously acquiring frequency hobbing includes the steps of: providing a receiving apparatus with a hobbing frequency sequence defining a hop order for a plurality of different frequencies; A sense frequency sequence that defines the hop order for a limited number of frequencies at the hop position described above is useful, and the transmitting device transmits the transmitted signal in accordance with the same frequency sequence as the hopping frequency sequence on the receiving side.
  • the carrier frequency is switched periodically, and the receiving device fast hops the receiving frequency according to the sense frequency sequence at a switching speed of approximately one cycle of the sense frequency sequence within the successive period of each carrier frequency. And the carrier sense succeeds at a specific sense frequency.
  • the receiving apparatus starts from the hop location corresponding to the specific cell Nsu frequency in the hopping frequency sequence, characterized in that it shifts the frequency hobbing operation in accordance with the hobbing frequency shea one Ke Nsu.
  • the receiving apparatus sets the receiving frequency to the next hop starting from the hop position corresponding to the specific frequency in the hopping frequency sequence.
  • the frequency is switched to the frequency of the position, and when a carrier is detected within a predetermined time, the operation shifts to a periodic frequency hopping operation according to the hopping frequency sequence.
  • the transmitting device transmits a synchronization control packet including synchronization control information during a predetermined number of frequency hopping periods prior to data transmission.
  • the transmitting device may be notified of the number of remaining hops before the start of data transmission by the synchronization control bucket, and the receiving device S may control the start of the data receiving operation based on the information of the number of remaining hops. it can.
  • a frequency hobbing wireless communication system includes a frequency synthesizer for switching a frequency of an output signal, a detection circuit for detecting a received signal at an output signal frequency from the frequency synthesizer, and a processing circuit for processing an output signal of the detection circuit.
  • a demodulation circuit that demodulates the received signal by performing the above operation; a low-speed hobbing control unit that instructs the frequency synthesizer to switch the frequency at a predetermined cycle according to a hobbing frequency sequence that defines a hop order for a plurality of different frequencies; and the hobbing frequency.
  • the above-mentioned carrier frequencies are connected.
  • the high-speed hopping control means for instructing the frequency synthesizer to switch the frequency at a switching speed of about one cycle of the sense frequency sequence during the control period ⁇ , and the frequency synthesizer in the hopping mode by the high-speed hopping means.
  • hopping by the low-speed hopping means is started from a hop position corresponding to the specific frequency in the hobbing frequency sequence.
  • the hobbing mode switching means for switching to the mode is lowered.
  • FIG. 1 is a diagram for explaining a conventional standby-type carrier sensing method
  • FIG. 2 is a diagram showing an example of a frequency hobbing sequence
  • FIG. 3 is a diagram for explaining the relationship between a frequency hopping sequence, a hobbing synchronization period, and a data transmission / reception period in the wireless communication system according to the present invention
  • FIG. 4 is a diagram illustrating a carrier sense method according to the present invention.
  • FIG. 5 is a block diagram showing one embodiment of a main part of a transmission circuit in the wireless communication system of the present invention.
  • FIG. 6 is a block diagram showing one embodiment of a main part of a receiving circuit in the wireless communication system of the present invention.
  • FIG. 7 is a detailed view of the carrier sense circuit 40 shown in FIG. 6,
  • FIG. 8 is a diagram showing one embodiment of a hopping pattern table
  • FIG. 9 is a diagram showing one embodiment of a sense pattern table
  • FIG. 10 is a diagram for explaining the relationship between the frequency hopping sequence and the sense frequency sequence
  • FIG. 11 is a diagram showing a transmission bucket during a hobbing synchronization period
  • FIG. 12 is a diagram showing hopping performed by a receiving circuit in a wireless communication system of the present invention. This is a flowchart showing the synchronization acquisition procedure. Best form to carry out the invention
  • FIG. 3 shows a relationship between a carrier frequency hopping sequence, a hopping synchronization period T s allowed for a receiving device, and a data transmission / reception period T d in the wireless communication system of the present invention.
  • n types of carrier frequencies are used, and one cycle of the frequency hopping sequence consists of n hops from F (l) to F (n) until the carrier frequency hops from one frequency to the next.
  • the period (hop period T h) is a length that enables data transmission of, for example, about a few symbols (bits).
  • the total time of the hopping synchronization period T s and the data transmission / reception period T d is represented by It should be shorter than the sequence period.
  • the hopping synchronization period T s is the 30 hop period from the third hop F (3) to the second hop F (32) in the hopping sequence
  • the data transmission / reception period T d is Is the 100 hop period from the third hop F (33) to the first 32 hop F (133)
  • the period of “T s + T d” is one cycle of the hobbing sequence. Indicates that it is only one part.
  • the hopping synchronization period T s force is much shorter than the hopping sequence. Therefore, as in the case of observing the frequency change from one window provided on the time axis, within each hopping synchronization period Ts, only a part of the n types of frequencies constituting the frequency hobbing sequence is included. Cannot observe.
  • T s ⁇ T d
  • the relationship may be T s ⁇ T d.
  • the above hopping synchronization period A plurality of sets each including T s and the data transmission / reception period T d may be set.
  • T s may occupy a part of the hobbing sequence
  • T d may occupy one or more periods spanning the next hopping sequence.
  • each frequency applied to the frequency hopping in the high-speed mode executed by the receiving device is defined as a “sense frequency”, and a hopping sequence including a plurality of sense frequencies is referred to as a “sense frequency sequence”. I will say.
  • One sense frequency sequence consists of a limited number of sense frequencies discretely selected from a carrier frequency hopping sequence.
  • the number k of the sense frequencies is determined by the relationship between the carrier frequency hopping sequence period and the hobbing synchronization period Ts, as described later.
  • Each communication device is provided with a sense frequency sequence of a plurality of patterns (hereinafter referred to as a “sense pattern”) corresponding to a hopping pattern of a carrier frequency that can be used by the transmission / reception device.
  • the sense frequency sequence is composed of k types of sense frequencies from the first hop f (l) to the kth hop i (k), and each hop period T During h, the sense frequency hopping is repeated at the speed of one cycle of the sense frequency sequence.
  • the illustrated example shows that when the transmitting side sets the carrier frequency to the frequency of the third hop F (3) of the hopping sequence, it matches the frequency of the seventh hop f (7) of the sense frequency sequence.
  • FIG. 5 is a block diagram showing a main part of a transmission circuit of a transmission-side communication device.
  • 1 1 is the transmission data 10 and the two signal sequences 1 2 (I) and 1 2 (Q)
  • the output signals 1 2 (1) and 1 2 (Q) of the modulation circuit 11 are input to multipliers 13 A and 13 B, respectively, and are generated by the frequency synthesizer 19.
  • Quadrature modulation is performed by an I signal component 19 (I) of the carrier 19 and a Q signal component 19 (Q) orthogonal thereto.
  • the output of the multiplier is synthesized by the adder 14 and then transmitted as a radio signal via the band-pass filter 15 and the antenna 17.
  • Reference numeral 25 denotes a frequency hopping (FH) pattern memory which is useful for storing a plurality of frequency hopping sequences to be described later.
  • FH frequency hopping
  • One frequency hopping sequence is provided in accordance with a read signal 21 provided by the hopping controller 20.
  • Information 22 indicating the frequency belonging to is read out one after another.
  • the hopping control device 20 periodically reads out the frequency information from the FH pattern memory 25 and outputs this to the frequency synthesizer 19 as a frequency designation signal 23.
  • the frequency synthesizer 19 switches the output frequency in response to the frequency designation signal 23.
  • FIG. 6 shows a main part of a receiving circuit of the receiving communication device.
  • the signal received by the antenna 30 passes through the band-pass filter 31 and is input to the two multipliers 32A and 32B.
  • These multipliers 32 A and 32 B are supplied with orthogonal signal components 51 (1) and 51 (Q) of a detection signal 51 of a specific frequency generated by the frequency synthesizer 50, respectively. Thereby, quadrature detection of the received signal is performed.
  • the signal components orthogonal to each other output from the multipliers 32 A and 32 B are converted into signals 34 (1) and 34 (1) whose harmonic components have been removed by low-pass filters (LPF) 33 A and 33 B.
  • 34 (Q) is input to the demodulation circuit 35, the bit synchronization circuit 37, and the carrier sense circuit 40.
  • the demodulation circuit 35 demodulates the input signals 34 (1) and 34 (Q) in synchronization with the bit clock 38 generated by the bit synchronization circuit 37, and generates the received data 36. Output.
  • the hopping control device 55 is a hobbing control device that instructs the frequency synthesizer 50 to switch the frequency based on the frequency information 57 read from the FH pattern memory 60. Yes, and receives the bit clock 38 and bit synchronization completion signal 39 generated by the bit synchronization circuit 37, and the carrier sense signal 49 generated by the carrier sense circuit 40, and performs frequency hopping. Control behavior.
  • the hopping control device 55 is connected to a host processor (not shown) via a bus 59.
  • Reference numeral 56 denotes a read control signal given to the hopping pattern memory 60 by the hopping control device 55, and 58 denotes a frequency designation signal given to the frequency synthesizer 50 by the hopping control device 55.
  • FIG. 7 shows the configuration of the carrier sense circuit 40.
  • the signals 34 (I) and 34 (Q) from which the harmonic components have been removed by the LPFs 33 A and 33 B are input to the multipliers 41 A and 4 IB, and the respective signal values are squared. Thereafter, they are added by the adder 42.
  • the output 43 of the adder 42 is compared with a reference value (3 ⁇ 4 value) 45 by the comparing unit 44 and output as a carrier sense signal 49.
  • the carrier frequency of the received signal input from the antenna matches the frequency 51 of the detection signal output from the frequency synthesizer 50, the amplitude of the received signal (carrier) increases, and the adder output 4 3 Exceeds the standard value. If the carrier is detected in this manner, carrier sense signal 49 is turned on, and if not, carrier sense signal 49 is turned off.
  • FIG. 8 shows an example of the hobbing pattern table 61 stored in the FH pattern memory 60 of the receiving communication device.
  • the transmitting device also stores a similar hobbing pattern table in the FH pattern memory 25.
  • a plurality of hopping frequency sequences identified by hopping pattern IDs are stored in the hopping pattern memory 61.
  • Each hopping frequency sequence defines the hop order of n types of frequencies (fl to fn), with one cycle being n hops from F (l) to F (n).
  • the hopping frequency sequences HP 1 to HPX are The different patterns define the hop order of frequencies ⁇ 1-: f ⁇ .
  • FIG. 9 shows an example of the sense pattern table 62 stored in the F-pattern memory 60 together with the hobbing pattern table 61.
  • a plurality of sense frequency sequences SPl to SPx each corresponding to the hopping frequency sequence ⁇ ⁇ 1 to ⁇ ⁇ X are recorded, and each of the sense frequency sequences SPl to SPx is recorded.
  • x defines the order of hops of the sense frequency, with one cycle of k hops from f (l) to f (k).
  • the sense frequencies constituting the sense frequency sequence SP i are discretely selected from the corresponding hopping frequency sequence HP i, and the hop order of the sense frequency follows the hop order in the hobbing frequency sequence HP i .
  • the receiving device sets a high frequency for one cycle of the sense frequency sequence SP i.
  • the speed hobbing operation is performed, and the synchronization acquisition is completed within a predetermined number of frequency hopping periods by the transmitting device.
  • the switching speed of the sense frequency performed on the receiving side within one hop period Th of the carrier frequency that is, the number k of the sense frequencies forming one sense frequency sequence SP i is included in one cycle of the hopping frequency sequence HP i It is determined by the number n of wave numbers to be transmitted and the number of hops j in the hopping synchronization period T s, and k is a value larger than an integer value obtained by dividing n by j.
  • the sense frequencies forming the sense frequency sequence SP i include k numbers located at n / k hop intervals from each other. Apply the frequency of
  • nZ k 1 0 0.
  • the frequency at an arbitrary position F (q) in the hopping frequency sequence is selected as f (l).
  • F (q + 100), F (q + 200), F at 100 hop intervals from (q + 300),... are sequentially selected as f (2), f (3), f (4), and so on.
  • n / k is not evenly divisible, select k frequencies with intervals as integer values with the decimal part truncated. Therefore, the sense frequencies need not necessarily be at exact hop intervals in the hopping frequency sequence.
  • the sense frequency sequence SP 1 is formed by a frequency discretely selected from the hobbing frequency sequence HP i, one of the sense frequencies SP n 1 and n Z k hops of the carrier on the transmitting side is generated. A carrier that matches the frequency appears, and the carrier sense always succeeds within a predetermined period.
  • FIG. 11 shows a synchronization control packet transmitted by the transmitting device S during the hopping synchronization period T s.
  • 70 F (1), 70F (2) and 70F (3) are synchronization control buckets transmitted on the carriers of F (1), F (2) and F (3) of the hopping frequency sequence.
  • Each synchronization control packet has a length of 32 bits, for example, and includes a fixed pattern section 71A for bit synchronization and a hopping marker section 71B.
  • Information indicating how many hops after the packet is received into the data transmission / reception period Td is inserted into the hopping capability 71B. After the success, based on the hopping marker information detected from the received packet, the start of data packet transmission / reception operation is controlled.
  • FIG. 12 shows a flowchart of the synchronization acquisition control executed by the hobbing control device 55.
  • the synchronous control device S55 sets a hopping pattern ID for frequency hopping in the same hopping sequence as the transmitting device (step 101).
  • the hobbing pattern ID may be such that the control device 55 reads a value set in a register from an external device, or may be obtained from a host processor via the bus 59. Hopping pattern ID Then, the hopping frequency sequence HP i to be used and the corresponding sense frequency sequence SP i are uniquely determined.
  • step 10 2 After setting the value of the parameter indicating the hop position S in the sense frequency sequence SP i to the initial value “0” (step 10 2), the value of K is incremented by 1 (10 3) , K are determined to exceed the upper limit value k (104). If K is equal to or smaller than k, the sense frequency of the K-th hop f (K) in the sense frequency sequence SP i is read from the memory 60, a switch to this frequency is instructed to the synthesizer 50, and the timer is timed. Set t (105). Next, the output signal 49 of the carrier sense circuit 40 is checked, and it is determined whether or not the carrier can be sensed at the sense frequency of the K-th hop f (K) (106). If the carrier cannot be sensed, that is, if the carrier frequency of the received signal does not match the above-mentioned sense frequency, the system waits for the timer to time out (107), and returns to step 103 and thereafter. Repeat steps.
  • the detection frequency hops one after another in the sense frequency order defined in the sense frequency sequence S Pi.
  • the hop interval t of the sense frequency is related to t ⁇ T h when the hop interval of the carrier is T h, and as a result, as described in FIG.
  • the hop position SF () of the same frequency as the above sense frequency is selected from the hopping frequency sequence HP i of the memory 60.
  • X is searched (108).
  • the frequency of the N-th hop F (N) of the hopping frequency sequence HP i is read out, the switching to this frequency is instructed to the synthesizer 50, and the timer is set to the carrier frequency.
  • the value of the hop period Th is set (111).
  • the output signal 49 of the carrier sense circuit 40 is checked, and it is determined whether or not the carrier can be sensed at the frequency of the Nth hop F (N) (111). The carrier sense is repeated until the timer times out (1 15).
  • the receiving side succeeds in carrier sensing with the sense frequency f (7), and immediately after that, step 11 If the frequency on the receiving side is switched to the frequency of the next hop F (4) of F (3) in step 3, the carrier on the transmitting side remains at the frequency of hop F (3), so carrier sense is interrupted. .
  • the return of the carrier sense performed in the above steps 114 to 115 is to wait for the transmission side to switch to the frequency of the next hop F (4).
  • the timer is reset to the carrier frequency hop period Th.
  • bit synchronization processing bit synchronization processing: 117.
  • a hopping marker is detected from the output signal 36 of the demodulation circuit 35 (118), and when the timer times out (119), the reception packet is calculated from the above value of the power. It is determined whether or not this is the last synchronous control packet (120). If it is the last synchronous control packet, the process proceeds to step 128, and if not, the process proceeds to step 122.
  • Steps 121 to 127 are control operations for hobbing the reception frequency every period Th until the last synchronization control packet is received, and include steps 1 to n of the hop position parameters N. While incrementing by one in the range (121 to 123), the frequency of the Nth hop F (N) of the hopping frequency sequence HPi is read, and the synthesizer 50 is instructed to switch to this frequency. Then, the time Th is set in the timer (124). Each time a frequency hobbing is detected, a marker is detected (125), and when the timer times out (122), the process returns to step 121, unless the received packet is the last synchronous control packet. Repeat the above steps.
  • frequency hobbing in the data transmission / reception period Td starting from step 128 is executed.
  • the parameter C for controlling the number of hops in the data transmission / reception period T d is set to the initial value “1” (1 228), and then the hop position g
  • the parameter N ranges from 1 to While incrementing by 1 each time (1 2.9 to 13 1), read the frequency of the N-th hop F (N) of the hopping frequency sequence HP i and instruct the synthesizer 50 to switch to this frequency.
  • the count parameter C is incremented (133), and it is determined whether or not the value of C exceeds a predetermined value K (TO) (135). As long as the value does not exceed the predetermined value K (TO), the flow returns to step 1 29 to repeat the hop operation to the next frequency.
  • the upper processor may be notified that the data transmission / reception period Td has been entered.
  • the data transmission / reception period T d is a fixed-length period determined by the number of hops K (TO), but the length of the data transmission / reception period T d or the value of K (TO) is determined by the transmitting device. Alternatively, it may be specified in the data packet or message transmitted during the data transmission / reception period Td to the receiving device.
  • the control sequence proceeds to the next step “NEXT”.
  • the transmitting device continues to transmit a signalless carrier while periodically repeating frequency hopping with the same hopping frequency sequence HPi during a transmission suspension period, for example,
  • the above-mentioned “fNEXT” step may be set to step 121 and wait for reception of a synchronization control bucket in the next synchronization period T s.
  • the transmitting device a notifies the receiving device of a hopping pattern ID to be used in the next communication by a message transmitted in the data transmission / reception period Td, and the next time a new hopping frequency sequence HP i ′ is used.
  • the above “NEXT” step may be set to step 101, and the control operation starting from the high-speed search may be repeated on the receiving side. Even when the hopping pattern is not switched, the process may return to step 102 once after data transmission / reception.
  • the mobile station starts communication with the base station as the transmitting apparatus and the mobile station as the receiving apparatus, and performs data transmission from the mobile station in response to data received from the base station, the mobile station performs the data reception operation.
  • both the base station and the mobile station store the sense pattern table 62 shown in FIG. 9 in the memory, and the synchronization control packet is transmitted from the mobile station for a predetermined period (T s) prior to data transmission. Then, data transmission is performed after that, and the base station performs synchronization acquisition by the sense frequency hopping of the high-speed mode described in FIG. 12 and then receives the data. It is sufficient to shift to low-speed mode frequency hobbing.
  • the sense frequency sequence is formed by a limited number of frequencies discretely selected from the hopping frequency sequence, and the sense frequency sequence is formed within the hop period Th of each carrier of the received signal.

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Abstract

Système de radiocommunication à sauts de fréquence destiné à émettre et recevoir des signaux tandis qu'une fréquence d'onde porteuse subit des sauts périodiques selon une séquence de sauts prédéterminée. Ce système comprend un synthétiseur de fréquence (50) commutant la fréquence du signal de sortie, un circuit de détection (32) destiné à détecter un signal de réception à la fréquence du signal de sortie provenant du synthétiseur de fréquence, un circuit de démodulation (35) pour démoduler le signal de réception de la sortie du circuit de détection, ainsi qu'un contrôleur de sauts (55) permettant de commander le synthétiseur. Le contrôleur de sauts présente un mode de sauts de faible vitesse (102 à 106) pour émettre une instruction au synthétiseur de fréquence afin que celui-ci commute la fréquence pour un cycle prédéterminé selon une séquence de fréquences de sauts qui définit une séquence de sauts pour différentes fréquences, ainsi qu'un mode de sauts de haute vitesse (121 à 135) pour émettre une instruction au synthétiseur de fréquence afin qu'il commute la fréquence à une vitesse de commutation correspondant sensiblement à un cycle de la séquence de fréquences de détection au cours d'une période pendant laquelle chaque fréquence d'onde porteuse est maintenue selon une séquence de fréquences de détection qui définit une séquence de sauts d'un nombre limité de fréquences existant dans des positions de saut discrètes dans ladite séquence de fréquences de sauts. Lorsque la porteuse est détectée à partir de la sortie du circuit de détection alors que le synthétiseur de fréquence extrait une fréquence spécifique dans le mode de sauts de haute vitesse, le mode de fonctionnement passe en mode de sauts de faible vitesse, la position de saut correspondant à une fréquence spécifique dans la séquence de fréquences de sauts étant utilisée comme point de départ.
PCT/JP1996/000679 1996-03-15 1996-03-15 Systeme de radiocommunication a sauts de frequence et procede d'acquisition synchrone WO1997035397A1 (fr)

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JP2007072746A (ja) * 2005-09-07 2007-03-22 Fujitsu Ltd 情報アクセス・システムおよびアクティブ型非接触情報記憶装置
JP2007533241A (ja) * 2004-04-15 2007-11-15 コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ 周波数ホッピング・システムで使用するための装置
EP3197060A4 (fr) * 2014-08-07 2017-08-09 Huawei Technologies Co. Ltd. Procédé, dispositif et système de transmission de données
CN114448466A (zh) * 2022-02-10 2022-05-06 重庆大学 一种适用于电力物联网的跳频同步方法

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JP2007533241A (ja) * 2004-04-15 2007-11-15 コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ 周波数ホッピング・システムで使用するための装置
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EP3197060A4 (fr) * 2014-08-07 2017-08-09 Huawei Technologies Co. Ltd. Procédé, dispositif et système de transmission de données
CN114448466A (zh) * 2022-02-10 2022-05-06 重庆大学 一种适用于电力物联网的跳频同步方法
CN114448466B (zh) * 2022-02-10 2022-11-01 重庆大学 一种适用于电力物联网的跳频同步方法

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