KR19990016285A - Receiver for spread spectrum communication - Google Patents

Abstract

It is possible to realize a compact and inexpensive spread spectrum communication receiver by sharing a signal generator that causes an increase in circuit size. A reception device for receiving a signal converted into a frequency region higher than the signal frequency band at the same time as spectrum spreading, comprising: a signal generator 13 for generating a signal for performing frequency conversion from a reception signal band to a base band signal, and a reception signal; In order to spectral despread, the signal generator 13 which generates a signal supplied to the despreaders 21 and 22 is shared. As a result, the device scale of the reception device can be made smaller, and a compact and inexpensive reception device for spread spectrum communication can be realized.

Description

Receiver for spread spectrum communication

The present invention relates to a reception device for spread spectrum communication.

Referring to Fig. 6, a conventional spread spectrum communication receiver is described. In Fig. 6, 10 is an antenna, 101 is a frequency converter, l02 is a signal oscillator, 201 is a despreader, 23 is a despread synchronization error detector, 24 is a clock generator, 25 is a spread code generator, 301, 302 is a frequency converter, and 303 is A 90 degree phase shifter, 304 is a signal oscillator, 15 is a synchronization error detector, and 31 is a data demodulator.

The antenna 10 receives a signal that is spread spectrum and is converted into a higher frequency region than that of the signal frequency band, and based on the signal generated from the signal oscillator 110, the frequency converter 101 uses a lower frequency band. A despreading code for despreading generated from the spreading code generator 25 is used, and the despreading signal is despread by the despreader 201 to reproduce a signal before spreading by the transmitting side.

Thereafter, the signal before the spectrum spread on the reproduced transmitting side is detected by a detector composed of the frequency converters 301 and 302, the 90-degree phase generator 303, and the signal generator 304 to detect the received signal, and the data demodulator 31 Restore the transmission signal to The frequency converters 301 and 302 are used to synchronize the output signal of the signal oscillator 304 and the output of the frequency conversion lines 301 and 302 of the received signal with the received signal after the spectrum despreading input to the frequency converters 301 and 302. The synchronization error detector 15 detects the synchronization error and adjusts the phase of the signal generator 304 based on the output.

In this way, the conventional spread spectrum communication receiving device converts a received signal into a frequency, performs a spectrum despreading process, and then performs synchronous detection to obtain received data.

However, in a conventional receiving apparatus that does not perform a spread spectrum method as a conventional spread spectrum communication receiver, the number of signal generators that greatly contributes to the miniaturization of the receiving apparatus is reduced, so that the apparatus scale of the receiving apparatus can be reduced. Even if the direct detection method used for this purpose is employed as it is, there is a drawback that the apparatus scale of the receiving apparatus cannot be reduced.

That is, in the conventional spread spectrum communication receiver, since the received signal is frequency-converted once, then the spectrum despreading process is performed, and then synchronous detection is performed to obtain the received data. In the process of synchronous detection once before spreading and after spectral despreading, a second time is performed in one circuit. For this reason, even if it is a direct detection system with the structure as it is, after frequency conversion, a spectrum despreading process is performed and a synchronous detection is performed after that.

Therefore, even if frequency conversion is directly performed by the frequency converter 01, the received signal after the spectral despreading process by the despreader 201 is already converted into a baseband signal. It can be said that only the frequency converter 301, 302, the 90-degree phase generator 303 and the generator 304, and a synchronous detector is required. Therefore, the number of signal generators that greatly contribute to the miniaturization of the apparatus of the receiving apparatus cannot be reduced, and even if the direct detection method is adopted, the scale of the apparatus cannot be reduced.

As described above, even if the conventional apparatus for receiving spread spectrum communication uses a direct detection method capable of reducing the number of signal generators and reducing the size of the apparatus in the conventional receiving apparatus that does not perform the spread spectrum method. Since the number of signal generators cannot be reduced, there is a drawback that the size of the device cannot be reduced, and that the receiving apparatus becomes large in size and the price is high.

Accordingly, an object of the present invention is to provide a compact and inexpensive receiver for spread spectrum communication.

1 is a block diagram for explaining a first embodiment of the present invention.

FIG. 2 is an explanatory diagram for explaining the signal spectrum of each major part of FIG. 1; FIG.

3 is a block diagram for explaining a second embodiment of the present invention.

4 is a block diagram for explaining a third embodiment of the present invention.

5 is a block diagram for explaining a fifth embodiment of the present invention.

Fig. 6 is a block diagram for explaining a conventional apparatus for receiving spread spectrum communications.

* Explanation of symbols on the main parts of the invention

l 0: antenna

ll, 12: Frequency converter

13: signal generator

14: 90 degree phase machine

15: Sync Error Detector

21,22: despreader

23,28: Despread Synchronous Error Detector

24,29: Clock Generator

25,26: Spread Code Generator

27: phase synchronization means

31: data demodulator

In order to solve the above-mentioned problems, the spread spectrum communication receiving apparatus of the present invention receives a signal which is spread spectrum and is converted into a high frequency region and is based on a reference signal generated by the signal generator. Simultaneously convert the frequency into a frequency band of the signal, recover the signal by spectral despreading, control the signal generator based on phase information extracted from the restored signal, and change the frequency of the reference signal generated by the signal generator. In this way, the phase of the recovery signal is controlled so as not to change.

By the above means, a signal generator for generating a signal serving as a reference for performing frequency conversion from a received signal band and a signal generator for generating a reference signal for synchronous detection can be shared. Therefore, since the number of signal generators that cause an increase in the size of the receiving device can be reduced, the device scale of the receiving device can be reduced by that much, and a compact and inexpensive receiving device can be realized.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail, referring drawings.

1 is a block diagram for explaining a first embodiment of the present invention. 1, 10 is an antenna, ll, 12 is a frequency converter, 13 is a signal generator, 14 is a 90 degree phase shifter, 15 is a synchronization error detector, 21, 22 is a despreader, 23 is a despread synchronization error detector, 24 Is a clock generator, 25 is a spread code generator, and 3l is a data demodulator. Then, during the synchronous detection loop composed of the frequency converters (ll, 12), the signal generator (13), the 90-degree phase shifter (14), and the synchronous error detector (15), the despreaders (21, 22) and the despread synchronous error. A spectral despread loop composed of a detector 23, a clock generator 24, and a spread code generator 25 is formed.

The operation of FIG. 1 will be described. The antenna 10 receives a signal that is spread spectrum and is converted into a frequency region higher than the signal frequency band, and the signal generated by the signal generator 13 and the signal are 90 degrees in phase with the phase shifter 14. On the basis of the misalignment, the frequency converters 11 and 12 convert the frequency signals into baseband signal bands, respectively, and use the spreading code for despreading generated by the spreading code generator 25, respectively. Spectrum despreading to obtain a signal. In order to synchronize with the received signal input to the frequency converter (ll, 12), the synchronization error detector 15 detects the synchronization error based on the output of the despreaders 21, 22, The phase is adjusted.

With this arrangement, since the received data after the synchronous detection is obtained at the outputs of the despreaders 21 and 22, the signal transmitted from the transmitting side to the data demodulator 31 can be restored and obtained as a data output.

Next, the operation of Fig. 1 will be described again with reference to Fig. 2 showing signal spectra of respective parts of Figs. 1A to 1E.

FIG. 2A is a signal spectrum received by an antenna 110 and converted into a frequency region higher than that of the signal frequency band. The received signal is a spectrum spread spectrum around the carrier frequency fo. 2B is a spectrum of a fo signal in which the frequency generated by the signal generator 13 is the same as the carrier wave. Fig. 2C is a spectrum-spread received signal after frequency conversion is performed on the baseband. FIG. 2D is a spectrum of a despread spread code generated by the spread code generator 25. FIG. 2E shows a spectrum spread reception signal after frequency conversion is performed on the baseband representing the spectrum in FIG. 2C with the spread code generator 25 representing the spectrum in FIG. Signal spectrum after despreading with despreaders 21 and 22 using spreading code for despreading.

As shown in Fig. 2, it can be seen that even in this embodiment, reliable spectrum spreading is performed, and a received signal and a despread baseband signal converted into a frequency region higher than the signal frequency band are obtained correctly.

In this embodiment, in the conventional receiving apparatus that does not perform the spread spectrum method, since the frequency conversion is performed from the reception signal band to the baseband signal and the synchronization processing can be performed in the same manner as when the direct detection method is adopted, the reception is performed. A signal generator for generating a signal serving as a reference for performing frequency conversion from a signal band to a baseband signal and a signal generator for generating a reference signal for synchronous detection can be combined. Therefore, the number of signal generators that are the basis for increasing the device scale can be reduced, and the number of signal generators that can increase the device scale can be reduced, so that the device scale of the receiving device can be made smaller and smaller. And an inexpensive reception device for spread spectrum communication can be realized.

3 is a block diagram for explaining a second embodiment of the present invention. In addition, the same code | symbol is attached | subjected to the component part which has the same function as FIG. In FIG. 3, l0 is an antenna, ll, 12 is a frequency converter, 13 is a signal generator, 14 is a 90 degree phase shifter, 15 is a synchronous error detector, 21 and 22 are despreaders, and 23 is a despread synchronous error detector. Denotes a clock generator, 25 denotes a spread code generator, and 31 denotes a data demodulator. Then, during the synchronous detection loop composed of the frequency converters 11 and 12, the signal generator 13, the 90-degree phase shifter 14, and the synchronous error detector 15, the despreaders 21 and 22 and the despread synchronous error. A spectral despread loop composed of a detector 23, a clock generator 24, and a spread code generator 25 is introduced.

Receives a signal from the antenna 10 that is spread spectrum and is converted into a frequency region higher than the signal frequency band, and generates a signal generated by the signal generator 13 and the signal by 90 degrees with a phase shifter 14 by 90 degrees. Based on the shifted signals, the frequency converters 11 and 12 perform frequency conversion in the base band signal bands, respectively. Using the despreading code generated by the spread code generator 25, the despreaders 21 and 22 respectively perform spectral despreading. In order to synchronize with the received signal input to the frequency converters (ll, 12), the outputs of the despreaders (21, 22) are input to the synchronization error detector 15, where the synchronization error is detected, and this is used as a control signal. The signal generator 13 is supplied to adjust the phase.

As described above, since the received data after the synchronous detection is obtained at the outputs of the despreaders 21 and 22, the signal transmitted from the transmitting side to the data demodulator 31 can be recovered and obtained as a data output.

In general, in spread spectrum communication, the I-axis and the Q-axis of a transmission carrier are most often spread with the same type of spread code generated from one spreading code generator. In that case, it is obvious that the synchronization error of the despreading of the I-axis and the Q-axis of the received wave is necessarily the same as the synchronization tracking of the despreading necessary for the despreading process at the time of reception. Therefore, in that case, the despreading synchronization error detector 23 for performing the despreading synchronization tracking to the spread spectrum communication receiving apparatus outputs the outputs of each of the despreaders 21 and 22 on the I-axis side and the Q-axis side. It does not need to be based, and it is enough to base the output on either side.

Therefore, on the premise of receiving spread spectrum communication in which the I and Q axes of the transmission wave are spread by the same type of spread code generated by one spreading code generator, two corresponding to the I and Q axes are provided. Only the output of one of the despreaders 22 among the outputs of the despreaders 21 and 22 can be inputted to the despreading synchronous error detector 23 to perform synchronous tracking of the despreading, and the despreading synchronous error detector 23 is provided. The configuration can be simplified as the number of inputs decreases as compared with the case of the spread spectrum communication receiving apparatus according to the present invention shown in FIG.

As described above, even in the embodiment of Fig. 3, as in the case of employing the direct detection method in the conventional receiving apparatus that does not perform the spread spectrum method, it is possible to perform the frequency conversion from the received signal band to the baseband signal and perform synchronous processing. The signal generator for generating a signal serving as a reference for frequency conversion from the received signal band to the baseband signal and the signal generator for generating a reference signal for synchronous detection can be combined. As a result, the number of signal generators that are the basis for increasing the device scale can be reduced, so that the device scale of the receiving device can be reduced by that much, and a compact and inexpensive receiver for spread spectrum communication can be realized.

The block shown in FIG. 4 is for explaining the third embodiment of the present invention. In spread spectrum communication, in order to increase communication incompatibility, different types of spreading codes may be used for the I and Q axes of the transmission carrier, and the spread spectrum communication receiving device according to this embodiment corresponds to this. In addition, the same code | symbol is attached | subjected and demonstrated to the structural part which functions like this embodiment and the embodiment shown in FIG.

In Fig. 4, 10 is an antenna, ll, 12 is a frequency converter, 13 is a signal generator, 14 is a 90 degree phase shifter, 15 is a synchronization error detector, 21 and 22 are despreaders, 23 is a despread synchronization error detector, and Is a clock generator, 25 and 26 are spread code generators, 27 is phase synchronization means, and 3l is a data demodulator. Then, the despreaders 21 and 22 and the despread synchronous error detector during the synchronous detection loop composed of the frequency converters 11 and 12, the signal generator 13, the 90-degree phase shifter 14, and the synchronous error detector 15. (23), a spectral despreading loop composed of a clock generator 24, spreading code generators 25 and 26, and phase synchronization means 27 is introduced.

In the receiving apparatus according to the present embodiment, the signal 10 having a spectrum spread and converted into a frequency region higher than the signal frequency band is received by the antenna 10, and the signal generated by the signal generator 13 and the signal are 90-degree phase shifters. On the basis of the signal shifted phase by 90 degrees at (14), the frequency converters 11 and 12 are used for frequency conversion into baseband signal bands, respectively. The despreaders 21 and 22 perform spectral despreading using the despreading codes for despreading generated by the spread code generators 25 and 26, respectively. At this time, by the control of the phase synchronization means 27, the phase difference between the spread codes for despreading generated by the spread code generators 25 and 26, respectively, is fixed to a predetermined value. In order to synchronize with the received signal input to the frequency converters (ll, 12), the synchronization error detector 15 detects the synchronization error based on the outputs of the despreaders 21, 22 to phase out the signal generator 13. It is supposed to adjust.

With this configuration, since the received data after synchronous detection is obtained at the outputs of the despreaders 21 and 22, the signal transmitted from the transmitting side to the data demodulator 31 can be restored and obtained as a data output.

In order to increase communication incompatibility in spread spectrum communication, even when different types of spread codes are used in the I and Q axes of the transmission carrier, if the chip rates and periods of the two spread codes are the same, despreading at the time of reception is performed. As the synchronization tracking of the despreading required in the processing, it is obvious that the synchronization error of the despreading of the I-axis and the Q-axis of the received wave is necessarily the same. In that case, therefore, the despreading synchronization error detector 23 for performing despreading synchronization with the spread spectrum communication receiving apparatus is based on the outputs of both the despreaders 21 and 22 on the I-axis side and the Q-axis side. It does not have to be, and it is sufficient if it is based on the output of either.

Therefore, on the premise of receiving spread spectrum communication in which the I-axis and the Q-axis of the transmission wave have the same chip rate and period and are spread using different kinds of spreading codes, reception for spread spectrum communication according to the present invention shown in FIG. Like the apparatus, out of the outputs of the two despreaders 21 and 22 corresponding to the I-axis and the Q-axis, only the output of one despreader 22 is input to the despreading synchronous error detector 23 to synchronize the despreading. Can be done.

In addition, by controlling the spreading code generators 25 and 26 with the phase synchronizing means 27 so that the phase relationship between the two types of spreading codes used for despreading on the I-axis side and the Q-axis side coincides with the parameters of the spreading code on the transmission side, In case of spread spectrum communication that increases communication incompatibility and uses different kinds of spread codes in the I and Q axes of the transmission carrier, if the chip speed and the period of the two spread codes are the same, the spread code generator and spread The receiver can be realized only by the addition of sign phase synchronization means.

Of course, also in this embodiment, since the direct detection method is adopted in the conventional receiving apparatus that does not perform the spread spectrum method, the frequency conversion is performed from the reception signal band to the baseband signal and the synchronization processing can be performed. A signal generator for generating a signal serving as a reference for performing frequency conversion from a received signal band to a baseband signal and a signal generator for generating a reference signal for synchronous detection can be combined. As a result, the number of signal generators that are the basis for increasing the size of the device can be reduced, the device scale of the receiving device can be reduced by that amount, and a compact and inexpensive receiving device for spread spectrum communication can be realized.

A fourth embodiment of a spread spectrum communication receiver according to the present invention will be described using the block diagram of FIG. 5. In spread spectrum communication, in order to increase communication incompatibility, different types of spreading codes may be used in the I and Q axes of the transmission carrier. In particular, in order to increase incompatibility, the spreading code spread on the I and Q axes may be different, and the chip speed and the code length may also be different. It corresponded.

In the drawings, components having the same functions as those in FIG. 1 will be described with the same reference numerals.

In Fig. 5, l0 is an antenna, ll, 12 is a frequency converter, 13 is a signal generator, 14 is a 90 degree phase shifter, 15 is a synchronization error detector, 21 and 22 are despreaders, and 23 and 28 are despread synchronization error detectors. , 24 and 29 are clock generators, 25 and 26 are spread code generators, and 31 are data demodulators.

Then, during the synchronous detection loop composed of the frequency converters (ll, 12), the signal generator (13), the 90-degree phase shifter (14), and the synchronous error detector (15), the despreaders (21, 22) and the despread synchronous error. A spectral despreading loop composed of detectors 23 and 28, clock generators 24 and 29, and spread code generators 25 and 26 is introduced.

Also in this embodiment, the signal spread by the antenna 10 is received by the antenna 10, and the signal generated by the signal generator 13 is converted to a frequency region higher than the signal frequency band thereof. On the basis of the phase shift of 90 degrees, the frequency converters 11 and 12 frequency-convert the baseband signal bands, respectively, and use the spread signals for despreading generated by the spread code generators 25 and 26, respectively. The despreaders 21 and 22 perform spectral despreading.

In order to synchronize with the received signal input to the frequency converters 11 and 12, the synchronization error detector 15 detects the synchronization error based on the outputs of the despreaders 21 and 22, The phase is adjusted. With this arrangement, since the received data after the synchronous detection can be obtained at the outputs of the despreaders 21 and 22, the signal transmitted from the transmitting side to the data demodulator 31 can be restored and obtained as a data output.

In order to increase communication incompatibility in spread spectrum communication, different types of spreading codes are used on the I and Q axes of the transmission carrier, and the types of spread codes spread on the I and Q axes are different When the speed and code length are different, the despreading synchronization necessary for the despreading process at the time of reception is required to perform the despreading process completely independently on the I-axis side and the Q-axis side of the receiving wave.

In the spread spectrum communication receiver according to the present invention shown in FIG. 5, the despreader 21, the despread synchronization error detector 23, and the clock generator 24 are used to independently despread the I and Q axes. Spectral despreading consisting of spreading code generator 25 and its synchronous tracking loop and despreader 22, despreading synchronization error detector 28, clock generator 29, and spreading code generator 26. In order to increase the incompatibility of communication through spread spectrum communication by providing two kinds of spreading and synchronization synchronization loops, different types of spreading codes are used for the I and Q axes of the transmission carrier and the I and Q axes. The receiver can be realized even when the types of spreading codes spread by different types and the chip speed and the code length are also different.

Of course, also in the spread spectrum communication receiver according to the present invention shown in FIG. 5, the same method as the case where the direct detection scheme is employed in a typical receiver that does not perform the spread spectrum method, and the frequency from the received signal band to the baseband signal Since the synchronous processing can be performed simultaneously with the conversion, a signal generator for generating a signal serving as a reference for performing frequency conversion from a received signal band to a baseband signal and a signal generator for generating a reference signal for synchronous detection can be combined.

As a result, the number of signal generators on which the device scale is increased can be reduced, and the number of signal generators on which the device scale is increased can be reduced. And an inexpensive reception device for spread spectrum communication can be realized.

As described above, according to the spread spectrum communication receiving apparatus of the present invention, a signal generator for generating a signal serving as a reference for performing frequency conversion from a received signal band to a baseband signal and a signal generator for generating a reference signal for synchronous detection Since the number can be shared, the number of signal generators that cause an increase in the device scale can be reduced, and the device scale of the receiving device can be reduced by that amount.

Claims (8)

At the same time, the signal is spread and received in the high frequency region, and based on the reference signal generated by the signal generator, the signal is frequency-converted to the frequency band of the original signal, and the spectrum is despread to restore the signal. , Controlling the signal generator based on phase information extracted from the reconstruction signal, And changing the frequency of the reference signal generated by the signal generator so that the phase of the recovery signal does not change. Frequency converting means for receiving a signal which is simultaneously spread spectrum and converted into a high frequency region and frequency-converted to the original signal frequency band based on a reference signal generated by the signal generator with the received signal; Spectral despreading means for spectral despreading the output of the frequency converting means and restoring the received signal to an original signal; Phase error detection means for outputting phase error information of the signal generated by the received signal and the signal generator from the output of the spectrum despreading means; A control means for supplying the phase error information detected by the phase error detecting means to the signal generator and controlling the phase of the restored original signal not to change by changing the frequency of the reference signal generated by the signal generator. A spreading device receiving device, characterized in that the configuration. At the same time, the signal is converted into a high frequency region, and is frequency-transformed into the original signal frequency band based on two reference signals that are 90 degrees out of phase with the same frequency generated by the signal generator. At the same time, spectrum despreading restores the received signal to the original signal, extracts phase information from the restored signal, controls the signal generator based on the phase information, and generates the reference signal. And changing the frequency so that the phase of the recovery signal does not change. The original signal frequency band, respectively, based on the first and second reference signals that are spread out at the same time and receive signals converted into a high frequency region and are shifted 90 degrees out of phase with the same frequency generated by the signal generator. And first and second despreaders for frequency conversion and despread spectrum. A delay lock loop for synchronizing the spreading code spreading the received signal with the despreading spreading code outputted from the spreading code generating means is based on the first and second reference signals, and is applied to the original signal frequency band. The synchronization is performed based on either of the two types of received signals which are frequency-converted. By supplying the despreading spreading code to the first and second despreaders for spectral despreading, despreading the two types of received signals based on the first and second reference signals, respectively, and restoring the original Extract phase information from the signal of Controlling the signal generator based on the extracted phase information and controlling the phase of the restored original signal not to change by changing the frequency of the reference signal generated by the signal generator. Receiving device. 5. The apparatus for spread spectrum communication according to claim 4, wherein the despreading spread codes respectively supplied to the first and second despreaders are the same. At the same time, the signal is spread and is converted into a frequency region higher than that of the signal frequency band, and the original signal is respectively based on the first and second reference signals shifted 90 degrees out of phase at the same frequency generated by the signal generator. First and second despreaders for frequency converting into a signal frequency band of the spectrum signal and simultaneously despreading the spectrum, In order to despread the spectrum, despreading codes supplied to the first and second despreaders respectively output from the spreading code generating means are different in kind but are synchronized in time by maintaining a predetermined phase relationship. The delay lock loop for synchronizing the spreading code spreading the received signal with the spreading code for despreading has two kinds of receptions frequency-converted to the original signal frequency band based on the first and second reference signals. Based on either side of the signal, By supplying the despreading diffusion code to the first and second despreaders, the two types of received signals are despread based on the first and second reference signals, respectively, to phase out from the original signal reconstructed. Extract information, Controlling the signal generator based on the extracted phase information and controlling the phase of the restored original signal not to change by changing the frequency of the reference signal generated by the signal generator. Receiving device. At the same time, the signal is spread and is converted into a frequency region higher than that of the signal frequency band, and the original signal is respectively based on the first and second reference signals shifted 90 degrees out of phase at the same frequency generated by the signal generator. First and second despreaders for frequency converting into a signal frequency band of the spectrum signal and simultaneously despreading the spectrum, Two pairs of delay lock loops for synchronizing a spreading code for spreading the received signal with a spreading code for despreading from the spreading code generating means for spreading the spectrum, The two types of received signals which are frequency-converted into the original signal frequency bands based on the first and second reference signals, respectively, are synchronized with the spreading code spreading the received signal and the spreading code for despreading. Drunk, 2 frequency-converted into the original signal frequency band based on the first and second reference signals by supplying the synchronized despreading code for spectral despreading to the first and second despreaders, respectively. Despreading each kind of received signals to extract phase information from the restored original signal, Controlling the electric signal generator based on the extracted phase information and controlling the phase of the restored original signal not to change by changing the frequency of the reference signal generated by the signal generator. Receiving device. In a spread spectrum communication receiving device that spreads spectrum and receives a signal converted into a frequency region higher than the signal frequency band, And converting the received signal into an original frequency band and sharing signal generating means for spectral despreading of the received signal.