JP5563922B2 - Wireless communication device - Google Patents

Description

  The present invention relates to a wireless communication apparatus, and more particularly to a wireless communication apparatus that performs spread spectrum communication.

  As a wireless communication device that performs spread spectrum communication, for example, a radio wave (radio signal) transmitted from a GPS satellite is received, and position information (longitude and latitude) is received using time data transmitted by the radio signal. ) There is a GPS receiver to get. The GPS receiver described in Patent Document 1 receives a GPS signal including the same position information that is transmitted for a fixed time at a fixed period, and synchronously adds a plurality of frames of the received GPS signal in synchronization with the fixed period. ing. Then, the GPS signals (position information) having a good signal-to-noise ratio (S / N ratio) can be acquired because the noise components included in each frame are attenuated by synchronously adding the GPS signals of a plurality of frames.

  By the way, in spread spectrum communication, the timing of one cycle of the spread code of the received radio signal (received frame) and the spread code for despreading is usually matched, that is, if synchronization is not achieved, despreading (demodulation) is performed. Can not do it. Therefore, in general wireless communication devices, capture the timing of the spread code of the received radio signal (synchronization acquisition), and then maintain the timing at which the spread codes between transmission and reception are correlated (synchronization holding or synchronization tracking) There is a need to. Here, a radio communication frame generally includes a preamble, a unique word, control information, data, and a check code. The preamble is normally repeated repeatedly 101010... And is used for symbol synchronization (bit synchronization) on the receiving side. The unique word is a symbol sequence for frame synchronization, and the frame start position (more specifically, the start position of the symbol sequence after the control information) is defined by the frame synchronization, and demodulation (despreading) Is possible.

JP 2000-353297 A (paragraphs 0019 to 0026)

  By the way, in order to improve the reception sensitivity of spread spectrum communication, it is necessary to ensure synchronization even when the reception level of the radio signal is low. On the other hand, if the time required for synchronization acquisition becomes too long, reception of important control information and data may fail.

  The present invention has been made in view of the above problems, and an object thereof is to improve reception sensitivity while reliably receiving data.

A wireless communication device of the present invention is a wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium, and the receiver receives A synchronization acquisition unit that captures the timing of the spread code of the spread spectrum signal; and a despreading operation unit that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. More than the time required for synchronization acquisition processing for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the receiver to the receiver Information spread with a spreading factor lower than the spreading factor of the synchronization unit by the processing unit not shorter than the first spreading code and the second spreading code having the same chip rate as the first spreading code It possesses the door, wherein the processing unit is characterized in that the correlation between the second spreading code is composed of a low spreading code.

  In this wireless communication apparatus, the synchronization acquisition unit receives a frame at a timing when a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold over a plurality of predetermined bits. It is preferable to capture synchronization.

  In this wireless communication apparatus, the spread spectrum signal frame includes a frame synchronization unit between the processing unit and the information unit, and the synchronization acquisition unit detects a bit string of the frame synchronization unit to detect the frame. It is preferable to capture synchronization.

In this wireless communication apparatus, the spread spectrum signal frame has a frame synchronization unit between the processing unit and the information unit, and the processing unit has a bit sequence different from the frame synchronization unit in the second spreading. It is preferable that the synchronization acquisition unit captures frame synchronization by detecting the bit sequence of the frame synchronization unit after detecting the bit sequence of the processing unit.
A wireless communication device of the present invention is a wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium, and the receiver receives A synchronization acquisition unit that captures the timing of the spread code of the spread spectrum signal; and a despreading operation unit that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. More than the time required for synchronization acquisition processing for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the receiver to the receiver Information spread with a spreading factor lower than the spreading factor of the synchronization unit by the processing unit not shorter than the first spreading code and the second spreading code having the same chip rate as the first spreading code And the synchronization acquisition unit performs frame synchronization at a timing when a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold over a plurality of predetermined bits. It is characterized by capturing.
A wireless communication device of the present invention is a wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium, and the receiver receives A synchronization acquisition unit that captures the timing of the spread code of the spread spectrum signal; and a despreading operation unit that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. More than the time required for synchronization acquisition processing for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the receiver to the receiver Information spread with a spreading factor lower than the spreading factor of the synchronization unit by the processing unit not shorter than the first spreading code and the second spreading code having the same chip rate as the first spreading code And the frame of the spread spectrum signal has a frame synchronization unit between the processing unit and the information unit, and the processing unit has a bit string different from the frame synchronization unit in the second The synchronization acquisition unit is configured to detect frame synchronization by detecting the bit string of the frame synchronization unit after detecting the bit string of the processing unit.

  In this wireless communication apparatus, the synchronization acquisition unit has a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold value, and the bit sequence after despreading includes the frame synchronization. It is preferable to capture frame synchronization when it matches the bit string of the part.

  In this wireless communication apparatus, it is preferable that a spreading factor of the first spreading code is an integer multiple of a spreading factor of the second spreading code.

  In this wireless communication apparatus, it is preferable that the first spreading code is a longer sequence code than the second spreading code.

  In this wireless communication apparatus, it is preferable that a spreading factor of the information unit is variable.

A wireless communication device of the present invention is a wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium, and the receiver receives A synchronization acquisition unit that captures the timing of the spread code of the spread spectrum signal; and a despreading operation unit that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. More than the time required for synchronization acquisition processing for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the receiver to the receiver Information spread with a spreading factor lower than the spreading factor of the synchronization unit by the processing unit not shorter than the first spreading code and the second spreading code having the same chip rate as the first spreading code The processing unit is blank, and a plurality of sets of the synchronization unit and the processing unit are continuously included in the frame of the spread spectrum signal, and one of the synchronization unit and the processing unit is included. The length of the set does not match the sum of the period of the first spreading code and the time required for the synchronization acquisition process, and the synchronization unit includes a first synchronization unit for bit synchronization and a second synchronization unit for frame synchronization. The first synchronization unit and the second synchronization unit are respectively spread by two types of the first spreading codes having different correlation characteristics, and are included in the frame of the spread spectrum signal. A plurality of sets of the first synchronization unit and the processing unit, a group of the second synchronization unit and the processing unit, and a plurality of sets of the first synchronization unit, the processing unit, and the information unit. A set of the second synchronization unit and the processing unit is inserted, and the synchronization acquisition unit is A first synchronization acquisition unit that acquires the synchronization of the first synchronization unit, and a second synchronization acquisition unit that acquires the synchronization of the second synchronization unit, and after the bit synchronization is acquired by the first synchronization acquisition unit The second synchronization acquisition unit captures frame synchronization.

  In this wireless communication apparatus, it is preferable that the length of one pair of the synchronization unit and the processing unit matches the sum of the period of the first spreading code and the time required for the synchronization holding process.

  In this wireless communication apparatus, it is preferable that the processing unit is a section where radio waves are not transmitted.

  The wireless communication apparatus of the present invention has an effect that reception sensitivity can be improved while data is reliably received.

It is a block diagram which shows Embodiment 1 of this invention. It is a time chart for demonstrating operation | movement of the receiver in the same as the above. It is a flowchart for demonstrating operation | movement of the receiver in the same as the above. It is explanatory drawing of the spread spectrum signal in the same as the above. It is explanatory drawing of the spread spectrum signal in the same as the above. It is explanatory drawing of the spread spectrum signal in the same as the above. It is a time chart for demonstrating operation | movement of the receiver in Embodiment 2 of this invention. It is a flowchart for demonstrating operation | movement of the receiver in the same as the above. It is a flowchart for demonstrating another operation | movement of the receiver in the same as the above. It is a time chart for demonstrating operation | movement of the receiver in Embodiment 3 of this invention. It is a flowchart for demonstrating operation | movement of the receiver in the same as the above. It is a time chart for demonstrating another operation | movement of the receiver in the same as the above. It is a time chart for demonstrating another operation | movement of the receiver in the same as the above. It is a flowchart for demonstrating another operation | movement of the receiver in the same as the above. It is a time chart for demonstrating operation | movement of the receiver in Embodiment 4 of this invention. It is a block diagram of the receiver in Embodiment 5 of this invention.

(Embodiment 1)
As shown in FIG. 1, the wireless transmission / reception apparatus according to the present embodiment includes a transmitter 1 and a receiver 2. The transmitter 1 includes a synchronization spreading code generation unit 10, a communication spreading code generation unit 11, a spreading code selection unit 12, a spreading calculation unit 13, a data modulation unit 14, a transmission unit 15, and an antenna 16.

  The synchronization spreading code generator 10 generates a synchronization spreading code (pseudo random noise code: PN code) corresponding to the first spreading code. The communication spreading code generator 11 generates a communication spreading code (PN code) corresponding to the second spreading code. However, it is assumed that the chip rate of the synchronization spreading code and the chip rate of the communication spreading code are equal to each other.

  The spreading code selection unit 12 selects either the synchronization spreading code or the communication spreading code and outputs it to the spreading calculation unit 13. The spread calculation unit 13 multiplies the modulation data (baseband signal) input from the outside and the spread code (synchronization spread code or communication spread code) selected by the spread code selection unit 12 to generate a baseband signal To diffuse. Here, in one frame (communication frame) of the modulation data, a synchronization part composed of a synchronization bit string, a blank processing part not including data, and a bit string indicating information such as a transmission destination address, a transmission source address, and a message And an information part consisting of The spread code selection unit 12 selects and outputs a synchronization spread code when the modulation data is a synchronization unit and a processing unit, and selects and outputs a communication spread code when the modulation data is an information unit. Therefore, the spread calculation unit 13 outputs a signal (spread spectrum signal) in which the synchronization unit and the processing unit are spread with the synchronization spread code and the information portion is spread with the communication spread code.

  The data modulator 14 digitally modulates the spread spectrum signal. As a digital modulation method, for example, phase shift modulation such as BPSK or QPSK or frequency shift modulation is employed. The transmitter 15 performs signal processing such as frequency conversion, amplification, and frequency discrimination on the digitally modulated spread spectrum signal, and then radiates (transmits) the spread spectrum signal from the antenna 16 as a radio wave.

  On the other hand, the receiver 2 includes an antenna 20, a receiving unit 21, a synchronization spreading code generation unit 22, a synchronization acquisition unit 23, a communication spreading code generation unit 24, a despreading operation unit 25, and a data demodulation unit 26. . The receiving unit 21 amplifies the radio wave received by the antenna 20 or removes interference waves other than the desired wave by filtering, and then converts the received signal (digitally modulated spread spectrum signal) to an intermediate frequency band signal (IF signal). ). Further, the receiving unit 21 converts the received signal converted into the IF signal into a digital signal (received waveform data) and stores it in the buffer memory.

  The synchronization spreading code generation unit 22 generates the same spreading code as the synchronization spreading code generation unit 10 of the transmitter 1. Further, the communication spread code generator 24 generates the same spread code (PN code) as the communication spread code generator 11 of the transmitter 1.

  The synchronization acquisition unit 23 includes a plurality of correlators (not shown), and a plurality of comparators (not shown) that respectively compare the correlation values calculated by the correlators with a predetermined threshold value. An output unit (not shown) for outputting a synchronization parameter when the correlation value exceeds a threshold value in the comparator; The correlator is, for example, a conventionally known sliding correlator, and calculates the correlation value by multiplying the received waveform data by the synchronization spreading code and then integrating the product. Here, in the plurality of correlators, the spreading factor of the synchronization spreading code (the number of chips of the synchronization spreading code for one bit of the synchronization unit) is the same from the received waveform data stored in the buffer memory of the receiving unit 21. A plurality of received waveform data samples sequentially extracted by length (time length) are input. That is, reception signals (reception waveform data samples) subjected to correlation calculation by each correlator are shifted by the time length. Note that the synchronization parameter output from the output unit is information indicating the phase (timing) of the synchronization spreading code used in the correlation calculation by the correlator whose correlation value exceeds the threshold value.

  Based on the synchronization parameter, the despreading calculation unit 25 extracts the received waveform data sample having the same length as the spreading factor of the communication spreading code from the received waveform data stored in the buffer memory of the receiving unit 21 (correction). (Delay time to be calculated). Then, the despreading calculation unit 25 despreads the received waveform data sample extracted by correcting the obtained delay time and the communication spread code generated by the communication spread code generation unit 24. The data demodulator 26 demodulates the received signal after despreading (digitally modulated baseband signal) to acquire original data (baseband signal), and outputs the acquired data (demodulated data).

  Here, an example of a communication frame in the present embodiment is shown in FIG. In the illustrated example, the spreading factor (code length: Tcd) of the communication spreading code is 7 and the spreading factor of the synchronizing spreading code (code length: Tca = N × Tcd) is 28 (4 spreading factor of the spreading code for communication). Times). In the illustrated example, the synchronization spreading code and the communication spreading code have the same code string and chip rate except that the spreading factor is different.

  Next, the operation of the receiver 2 in this embodiment will be described in more detail with reference to the time chart of FIG. 2 and the flowchart of FIG.

  In this embodiment, as shown in FIG. 2, the five correlators included in the synchronization acquisition unit 23 sequentially and cyclically calculate the correlation values between the received waveform data samples and the synchronization spreading code (see FIG. 3). ). If the correlation value (synchronization correlation value) calculated by any correlator exceeds the threshold value, it is necessary until the correlation value exceeds the threshold value after the correlator starts the correlation value calculation. The time Td is the delay time to be corrected. The received waveform data stored in the buffer memory of the receiver 21 is delayed by a time Tx required for processing such as frequency conversion to an intermediate frequency and A / D conversion to a digital signal with respect to the received signal. The delay time Td detected by the synchronization acquisition unit 23 matches the delay time Tx. Here, since the time length of the processing unit following the synchronization unit is set to a time that is not shorter than the time required for the synchronization acquisition process of the synchronization acquisition unit 23, when the synchronization acquisition unit 23 acquires the synchronization, Information section reception has not started. Therefore, the despreading calculation unit 25 performs a process (delay correction process) for delaying the timing of extracting the received waveform data from the buffer memory of the reception unit 21 based on the synchronization parameter (delay time Td) output from the synchronization acquisition unit 23. The received waveform data after the delay correction processing is multiplied by the communication spreading code and despread. Therefore, when the despreading calculation unit 25 executes the delay correction process, bit synchronization and frame synchronization of the spread spectrum signal are established, and the data demodulation unit 26 can demodulate the data in the information unit.

  As described above, in the present embodiment, the communication frame includes the synchronization unit, the processing unit, and the information unit. The synchronization unit is spread with a synchronization spreading code having a higher spreading factor than the communication spreading code of the information unit (the code length of the spreading code is long), and the processing unit is not shorter than the time required for the synchronization acquisition process Is set to Therefore, even if the reception intensity (signal level) of the reception signal (spread spectrum signal) received by the reception unit 21 is relatively lowered, synchronization can be reliably established in the receiver 2. For example, as shown in FIG. 4, if the spreading factor (= 28) of the synchronization spreading code is four times the spreading factor (= 7) of the communication spreading code, it is four times longer than the information part. Synchronization can be acquired over time. Therefore, the S / N ratio can be improved by about 4 times compared to the case where the spreading factors of the two spreading codes are equal. As a result, in the wireless communication apparatus of this embodiment, it is possible to improve reception sensitivity while reliably receiving data.

  Here, the spreading code (synchronous spreading code) of the synchronization unit shown in FIG. 4 is configured by a code (0111001) of the same sequence as the spreading code (communication spreading code) of the information unit. On the other hand, as shown in FIG. 5, the synchronization spreading code may be composed of a series of codes longer than the communication spreading code. That is, in FIG. 5, a PN code (0111001) with 7 chips is used for the communication spreading code, whereas a PN code (1110110011100001101010010001011) with 31 chips is used for the synchronization spreading code. . In this way, the side lobe of the communication spreading code is 1/7 of the maximum correlation value, whereas the side lobe of the synchronization spreading code is 1/31 of the maximum correlation value. Therefore, since side lobes are reduced as compared with the spreading code for synchronization shown in FIG. 4, synchronization can be established reliably even at a lower reception strength.

  By the way, in the example shown in FIG. 4, the ratio of the spreading factor of the synchronization spreading code (= 28) and the spreading factor of the communication spreading code (= 7) is 4: 1. However, the ratio of the diffusivities of both is not limited to 4: 1 and can be arbitrarily selected. However, when the spreading factor of the synchronization spreading code is an integral multiple of the spreading factor of the communication spreading code, for example, when the spreading factor of the synchronizing spreading code is 28 as shown in FIG. 14 is preferable. This is because if the respective spreading factors of the synchronization spreading code and the communication spreading code are set in this way, the communication rate (without changing the type of PN code and the synchronization acquisition processing of the synchronization acquisition unit 23) (Transmission rate) can be varied.

(Embodiment 2)
The present embodiment is different from the first embodiment in that the synchronization acquisition unit 23 of the receiver 2 includes only one correlator and the time length of the synchronization unit in the communication frame is long. It is common with Form 1. Therefore, the same components as those in the first embodiment are denoted by the same reference numerals, and illustration and description thereof are omitted.

  In the receiver 2 of the first embodiment, the plurality of correlators included in the synchronization acquisition unit 23 execute the calculation of the correlation value in parallel, whereas in the receiver 2 of the present embodiment, the synchronization acquisition unit 23 The one correlator included in is executing the correlation value calculation. Therefore, the time length of the synchronization unit in the present embodiment is a time sufficiently longer than the time length of the synchronization unit in the first embodiment, specifically, the time length of the processing unit is equal to the time of two cycles of the synchronization spreading code. The time length is set by adding the length. The correlation value calculation in the correlator is the same as that in the first embodiment.

  Next, the operation of the receiver 2 in this embodiment will be described in more detail with reference to the time chart of FIG. 7 and the flowchart of FIG.

  In the present embodiment, one correlator provided in the synchronization acquisition unit 23 sequentially calculates the correlation value between the received waveform data sample and the synchronization spreading code (see FIG. 8). If the correlation value (synchronization correlation value) between any received waveform data sample and the synchronization spreading code exceeds the threshold, the correlator starts calculating the correlation value of the received waveform data sample. The time Td required to exceed the threshold value is the delay time to be corrected. Here, the time length of the synchronization unit is set to a time obtained by adding the time length of two cycles of the synchronization spreading code to the time length of the processing unit, and the time length of the processing unit is the synchronization acquisition process of the synchronization acquisition unit 23 It is set to a time not shorter than the time required for. Therefore, when the synchronization capturing unit 23 captures synchronization, reception of the information unit has not yet started. Therefore, the despreading calculation unit 25 performs a process (delay correction process) for delaying the timing of extracting the received waveform data from the buffer memory of the reception unit 21 based on the synchronization parameter (delay time Td) output from the synchronization acquisition unit 23. The received waveform data after the delay correction processing is multiplied by the communication spreading code and despread. Then, when the despreading calculation unit 25 corrects the delay time, the bit synchronization of the spread spectrum signal is established.

  Further, the correlator of the synchronization acquisition unit 23 calculates the correlation value between the received waveform data sample and the communication spreading code bit by bit in a state where the bit synchronization is established (synchronization holding state). Here, the received waveform data is indefinite because there is no bit string in the processing unit following the synchronization unit. Therefore, since the correlation value between the communication spread code and the received waveform data sample is usually low, the correlation value calculated by the correlator is below the threshold value. When the received waveform data sample of the information section is input, the correlation value calculated by the correlator immediately exceeds the threshold value, so that frame synchronization is established when the correlation value exceeds the threshold value. Therefore, after frame synchronization is established, if the despreading calculation unit 25 despreads the received waveform data sample with the communication spreading code at the same timing as the correlation value calculation by the correlator of the synchronization acquisition unit 23, the data demodulation unit 26 Can demodulate the data in the information section.

  However, as shown in the flowchart of FIG. 9, when all the correlation values between the received waveform data for a plurality of bits (for example, 4 bits) from the beginning of the information part and the spread code for communication exceed the threshold value, The capturing unit 23 may determine that frame synchronization has been established. If such a determination process is performed by the synchronization capturing unit 23, it is possible to reliably capture (establish) frame synchronization even when the reception strength of the received signal further decreases.

  By the way, if the processing unit is blank, the correlation value between the received waveform data of the processing unit and the communication spreading code should be less than the threshold value as described above. However, the correlation value between the received waveform data of the processing unit and the communication spread code may exceed a threshold value due to a noise component included in the received signal. Therefore, it is preferable that the processing unit is configured by a spreading code having a low correlation with the communication spreading code, that is, a cross-correlation characteristic with the communication spreading code being small. For example, the communication spreading code and the processing unit may be configured with two types of code sequences having small cross-correlation characteristics selected from Gold-series PN codes.

  In this way, if the processing unit is configured with a spreading code having a low correlation with the communication spreading code, the influence of the noise component included in the received signal is reduced compared to when the processing unit is blank, and the frame Synchronization can be reliably established (captured).

(Embodiment 3)
The present embodiment is different from the first and second embodiments in the frame structure of the spread spectrum signal and the frame synchronization capturing method by the synchronization capturing unit 23, and is otherwise the same as the first or second embodiment. Therefore, the same code | symbol is attached | subjected to the same structure as Embodiment 1 or 2, and illustration and description are abbreviate | omitted.

  As shown in FIG. 10, the spread spectrum signal frame in the present embodiment has a frame synchronization unit between the processing unit and the information unit. The processing unit is configured by a PN code having a low correlation with the communication spreading code. The frame synchronization unit corresponds to a unique word, and a bit string of a specific pattern (for example, a bit string of a pattern in which “1” continues for a time length matching the synchronization spreading code length Tca) is spread with a communication spreading code. ing.

  Next, the operation of the receiver 2 in this embodiment will be described in more detail with reference to the time chart of FIG. 10 and the flowchart of FIG.

  In the present embodiment, as in the second embodiment, one correlator provided in the synchronization acquisition unit 23 sequentially calculates the correlation value between the received waveform data sample and the synchronization spreading code (see FIG. 10). Then, when the synchronous correlation value calculated by any correlator exceeds the threshold, the time required from the time when the correlator starts the correlation value calculation of the received waveform data sample to exceed the threshold Td is the delay time to be corrected. Then, when the despreading calculation unit 25 corrects the delay time, the bit synchronization of the spread spectrum signal is established.

  Further, the despreading calculation unit 25 despreads the received waveform data sample with the communication spreading code in the bit synchronization synchronized holding state, and the data demodulation unit 26 demodulates the received waveform data sample after despreading. At this time, since the received waveform data sample of the processing unit is spread with a PN code having a low correlation with the communication spreading code, it cannot be despread with the communication spreading code. On the other hand, the received waveform data sample of the frame synchronization unit spread by the communication spreading code can be despread by the communication spreading code, and can be demodulated by the data demodulation unit 26. Therefore, the frame synchronization is captured (established) when the data demodulation unit 26 can demodulate the data and the frame synchronization unit is detected. Therefore, if frame synchronization is established, the data demodulator 26 can demodulate the data in the information part from the received waveform data sample despread by the despreading calculator 25.

  Here, in the processing unit, a bit string having a pattern different from the bit string of the frame synchronization unit (for example, a bit string having a pattern in which “0” is continuous) may be spread with a communication spreading code (see FIG. 12). In this case, if the despreading calculation unit 25 despreads the received waveform data sample with the communication spreading code in the synchronization holding state, and the data demodulation unit 26 demodulates the received waveform data sample after despreading, the bit string of the processing unit The bit string of the frame synchronization unit can be clearly identified. Therefore, the frame synchronization unit can be detected more reliably.

  Further, after the bit synchronization is established, the correlator calculates the correlation value between the received waveform data sample and the communication spread code, and the correlation value exceeds the threshold value, and the data demodulator 26 demodulates the bit string of the frame synchronization unit. At this point, frame synchronization may be established (see the time chart in FIG. 13 and the flowchart in FIG. 14).

(Embodiment 4)
By the way, for radio stations used in Japan, the characteristics of radio waves used (RF characteristics) such as occupied frequency bandwidth and adjacent channel leakage power must satisfy the regulations of the Radio Law. In the Radio Law, different standards (communication standards) are defined for each purpose of use. For example, “low-power radio stations” defined as one of the radio stations that do not require a license in the proviso to Article 4 of the Radio Law include “wireless stations for cordless telephones”, “specified low-power radio stations”, “low-power radio stations” Security system "," Radio station of low power data communication system ", etc. And the standard is prescribed | regulated by the equipment rule of the law enforcement regulations about the radio equipment of each radio station. For example, according to Article 49-17 “Radio Equipment of Radio Stations of Low Power Security System” of Radio Equipment Regulations of the Radio Law Enforcement Regulation, the period during which radio signals may be continuously transmitted (transmission period) is 3 seconds or less It is stipulated that a period during which a radio signal should not be transmitted (pause period) provided between a transmission period and a transmission period is 2 seconds or more (see No. 5 of the same article).

  On the other hand, in Embodiments 1 to 3 described above, the time (transmission time) for transmitting one frame of radio signal (digitally modulated spread spectrum signal) from the transmitter 1 is relatively longer by the amount of the processing unit. It has become. Therefore, there is a possibility that the number of radio signal frames that can be transmitted within the transmission period is relatively small.

  Therefore, in the present embodiment, a plurality of sets of processing units and synchronization units consisting of blanks are continuously included in one frame of the spread spectrum signal, and the length of one set is one period of the synchronization spreading code. It is set to a time that does not match the sum of the processing times of the synchronization acquisition process (see FIG. 15). The synchronization unit is set to a time length twice as long as the synchronization spreading code length Tca. However, since the configurations of the transmitter 1 and the receiver 2 in the present embodiment are the same as those in the second embodiment, the same components are denoted by the same reference numerals, and illustration and description thereof are omitted.

  After transmitting the radio signal of the synchronization unit, the transmitter 1 pauses the transmission of the radio signal in the blank processing unit. That is, the transmitter 1 intermittently transmits a radio signal for one frame, and power consumption is reduced by the amount of the pause period. In addition, since the processing unit corresponds to the suspension period, the regulation of the suspension period defined in the above-described “radio equipment of the wireless station of the low power security system” is satisfied.

  On the other hand, the receiver 2 performs a synchronization acquisition process on received waveform data samples extracted with the same time length as the synchronization spreading code length Tca. Here, if the processing time required for the synchronization acquisition processing by the synchronization acquisition unit 23 is Tm and the time length of the processing unit is Tb, the relationship Tca × 2 + Tb> Tca + Tm is established. The synchronization acquisition unit 23 adjusts the processing time Tm to Tm = Tca + Tb once the synchronization is acquired. As a result, since the relationship Tca × 2 + Tb = Tca + Tm is established after synchronization acquisition, the synchronization acquisition unit 23 can maintain synchronization (bit synchronization) even across the processing units.

  Further, the correlator of the synchronization acquisition unit 23 calculates the correlation value between the received waveform data sample and the communication spread code bit by bit. When the received waveform data sample of the information section is input, the correlation value calculated by the correlator immediately exceeds the threshold value, so that frame synchronization is established when the correlation value exceeds the threshold value. Therefore, after frame synchronization is established, if the despreading calculation unit 25 despreads the received waveform data sample with the communication spreading code at the same timing as the correlation value calculation by the correlator of the synchronization acquisition unit 23, the data demodulation unit 26 Can demodulate the data in the information section.

(Embodiment 5)
Since the configurations of the transmitter 1 and the receiver 2 in this embodiment are the same as those in the second embodiment, the same components are denoted by the same reference numerals, and illustration and description thereof are omitted.

  The spread spectrum signal of the present embodiment includes a first synchronization unit for bit synchronization spread with a spreading code for synchronization and a second synchronization unit (unique word) for frame synchronization spread with a spread code for communication. A first synchronization unit and a plurality of sets of processing units, a second synchronization unit and a set of the processing units are included, and the second synchronization unit and the plurality of sets of processing units and the information unit A pair of a synchronization unit and a processing unit is inserted. That is, the second synchronization unit and processing unit pair is inserted after the last combination of the first synchronization unit and processing unit, and the information unit immediately follows the second synchronization unit and processing unit group. .

The synchronization acquisition unit includes a first synchronization acquisition unit that acquires synchronization of the first synchronization unit, and a second synchronization acquisition unit that acquires synchronization of the second synchronization unit. After capturing bit synchronization, the second synchronization capturing unit captures frame synchronization. On the other hand, the receiver 2 includes a first synchronization capturing unit 27 that captures bit synchronization from the first synchronization unit as shown in FIG. And a second synchronization acquisition unit 28 for acquiring frame synchronization from the second synchronization unit.

  The first synchronization acquisition unit 27 executes the same synchronization acquisition process as the synchronization acquisition unit 23 in the fourth embodiment to acquire bit synchronization. The second synchronization acquisition unit 28 despreads the received waveform data sample with a communication spreading code while maintaining bit synchronization. At this time, the received waveform data sample of the first synchronization unit spread by the synchronization spreading code cannot be despread by the communication spreading code. On the other hand, the received waveform data sample of the second synchronization unit spread by the communication spreading code can be despread by the communication spreading code. Therefore, frame synchronization is captured (established) when the second synchronization unit is detected by the second synchronization acquisition unit 28. If frame synchronization is established, the data demodulator 26 can demodulate the data in the information section from the received waveform data sample despread by the despreading calculator 25.

1 Transmitter (wireless communication device)
2 Receiver (wireless communication device)
22 Synchronization spreading code generator
23 Synchronization acquisition unit
24 Communication spread code generator
25 Despreading operation unit

Claims (13)

A wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium,
The receiver includes a synchronization acquisition unit that captures a timing of a spread code of the received spread spectrum signal, and a despreading operation that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. With
It is necessary for the synchronization acquisition process for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the transmitter to the receiver. A processing unit having a time not shorter than the time and a second spreading code having a chip rate equal to that of the first spreading code, and an information unit spread at a spreading factor lower than that of the synchronizing unit. And
The wireless communication apparatus , wherein the processing unit includes a spreading code having a low correlation with the second spreading code . The synchronization acquisition unit captures frame synchronization at a timing when a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold over a plurality of predetermined bits. The wireless communication apparatus according to claim 1. The spread spectrum signal frame includes a frame synchronization unit between the processing unit and the information unit, and the synchronization acquisition unit detects frame synchronization by detecting a bit string of the frame synchronization unit. The wireless communication apparatus according to claim 1 . The frame of the spread spectrum signal has a frame synchronization unit between the processing unit and the information unit, and the processing unit is formed by spreading a bit string different from the frame synchronization unit with the second spreading code. the synchronization acquisition unit, after detecting the bit sequence of the processing unit, the wireless communication apparatus according to claim 1, wherein the capture frame synchronization by detecting the bit sequence of the frame synchronization unit. A wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium,
The receiver includes a synchronization acquisition unit that captures a timing of a spread code of the received spread spectrum signal, and a despreading operation that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. With
It is necessary for the synchronization acquisition process for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the transmitter to the receiver. A processing unit having a time not shorter than the time and a second spreading code having a chip rate equal to that of the first spreading code, and an information unit spread at a spreading factor lower than that of the synchronizing unit. And
The synchronization acquisition unit captures frame synchronization at a timing when a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold over a plurality of predetermined bits. No line communication apparatus according to. A wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium,
The receiver includes a synchronization acquisition unit that captures a timing of a spread code of the received spread spectrum signal, and a despreading operation that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. With
It is necessary for the synchronization acquisition process for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the transmitter to the receiver. A processing unit having a time not shorter than the time and a second spreading code having a chip rate equal to that of the first spreading code, and an information unit spread at a spreading factor lower than that of the synchronizing unit. And
Further, the frame of the spread spectrum signal has a frame synchronization unit between the processing unit and the information unit, and the processing unit has a bit string different from that of the frame synchronization unit spread by the second spreading code. becomes Te, the synchronization acquisition unit, after detecting the bit sequence of the processing unit, radio communications device characterized by capturing the frame synchronization by detecting the bit sequence of the frame synchronization unit. The synchronization acquisition unit has a correlation value when the spread spectrum signal is despread with the second spreading code exceeds a predetermined threshold value, and the bit sequence after despreading matches the bit sequence of the frame synchronization unit The radio communication apparatus according to any one of claims 3, 4 and 6 , wherein the frame synchronization is sometimes captured . The spreading factor of the first spreading code, the radio communication apparatus according to any one of claims 1-7, characterized in that an integral multiple of the spreading factor of the second spreading code. The radio communication apparatus according to any one of claims 1 to 7 , wherein the first spreading code is a code having a longer sequence than the second spreading code . The wireless communication apparatus according to any one of claim 1 to 9, wherein the spreading factor of the information portion is variable. A wireless communication device that includes a transmitter and a receiver and transmits a spread spectrum signal from the transmitter to the receiver using radio waves as a medium,
The receiver includes a synchronization acquisition unit that captures a timing of a spread code of the received spread spectrum signal, and a despreading operation that multiplies the spread spectrum signal by the spread code in synchronization with the timing captured by the synchronization acquisition unit. With
It is necessary for the synchronization acquisition process for capturing the timing of the first spreading code and the synchronization unit spread by the first spreading code in the spread spectrum signal frame transmitted from the transmitter to the receiver. A processing unit having a time not shorter than the time and a second spreading code having a chip rate equal to that of the first spreading code, and an information unit spread at a spreading factor lower than that of the synchronizing unit. And
The processing unit is blank, and a plurality of sets of the synchronization unit and the processing unit are continuously included in a frame of the spread spectrum signal, and the length of one set of the synchronization unit and the processing unit is , Does not coincide with the sum of the period of the first spreading code and the time required for the synchronization acquisition process,
The synchronization unit includes a first synchronization unit for bit synchronization and a second synchronization unit for frame synchronization, and the first synchronization unit and the second synchronization unit are of two types having different correlation characteristics. Each of the first spread codes is spread, and the spread spectrum signal frame includes a plurality of sets of the first synchronization unit and the processing unit, and a set of the second synchronization unit and the processing unit. A pair of the second synchronization unit and the processing unit is inserted between the plurality of sets of the first synchronization unit and the processing unit and the information unit,
The synchronization acquisition unit includes a first synchronization acquisition unit that acquires synchronization of the first synchronization unit, and a second synchronization acquisition unit that acquires synchronization of the second synchronization unit. after capturing the bit synchronization, radio communications apparatus characterized by capturing the frame synchronization at the second acquisition unit. 12. The wireless communication apparatus according to claim 11 , wherein a pair of lengths of the synchronization unit and the processing unit is equal to a sum of a period of the first spreading code and a time required for synchronization holding processing . The wireless communication apparatus according to claim 12 , wherein the processing unit is a section where radio waves are not transmitted .

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