JPH10308719A - Device and method for decoding spread spectrum signal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device for compounding spread spectrum signals while compensating them while using one correlator by generating a correlative signal concerning the chip of spread spectrum signal and the chip of signal corresponding to a code having a length L, and directly generating plural data symbols in response to the comparison of correlative signal with plural threshold levels. SOLUTION: The received spread spectrum signal, which is modulated by a PN code and has a data signal is stored in a reception register 39 and the full length L of 1st pseudo noise signal is stored in a 1st reference register 33. Concerning a modulo 2, the respective chips of received spread spectrum signal are added to the respective chips of 1st reference pseudo noise signal by a 1st adder 40. This modulo addition of two signals generates plural 1st chip compare signals as a result and these signals are sent from the 1st adder 40 to a 1st adder 41. The 1st adder 41 adds the plural 1st signals and generates the 1st correlative signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to spread spectrum communication, and more particularly, to an apparatus and method for decoding a spread spectrum signal used in a non-code synchronous spread spectrum communication system.

[0002]

2. Description of the Related Art A spread spectrum system is one in which a signal is spread over a band that is much wider than the maximum bandwidth required to transmit the information to be transmitted. Techniques for direct sequence spread spectrum modulation have been developed over the years to establish more secure communications. Modulation is performed by mixing the information to be sent with a periodic pseudo noise (PN) code. The result is a sin (X) / X signal that has a very wide bandwidth and small spectral density compared to the above information. This spectral density reduces interference with other wireless sensing devices and reduces the signal's sensitivity to in-band interference and jamming. Among other advantages, the ability of selective addressing, code division multiplexing for multiple access, and the capability of frequency ranges with high accuracy,
Specific to spread spectrum systems.

[0003] Due to the encoded nature of the signal, demodulation is a process that involves more than the process of a conventional traditional communication system, which is transmitted and synchronized with the received code. And the same reference code as the reference code. The difficulty in this process is that it does not indicate the degree of asynchrony between the received code and the reference code until a very high degree of code synchronization is performed. Further, mismatches between the transmit and receive oscillators used to generate the PN code tend to cause drift in the synchronization between the transmitter and the receiver.

The prior art communication system using two pseudo-random waveforms and two correlators for indicating a mark or space, Hauer on January 27, 1981 (Hau
U.S. Pat. No. 4,247,94 issued to U.S. Pat.
No. 2 and incorporated herein by reference. Haua
Over in some communication systems, for supplying successive input pulses to the delay line, discloses a first delay line having a plurality of taps with a space from each other. Pulses that are variously delayed in response to each input impulse appear at the taps of the delay line used to generate the pulse representing the mark or space. His disclosure includes a plurality of synchronous detectors and means for providing a plurality of pulses transmitted on the carrier to the plurality of detectors.

[0005]

The prior art does not disclose or suggest an apparatus for acquiring a spread spectrum signal using a single correlator, and does not disclose a time period of one data bit on each data bit. It does not disclose or suggest a device having an equivalent spread spectrum signal acquisition time. Further, the prior art does not teach double threshold detection in one correlator such that the first and second data symbols can be determined with equal accuracy in one correlator. Using multiple threshold detection correlators to double the data rate for each additional double threshold detection correlator without increasing code rate or signal acquisition time. Not teaching.

It is an object of the present invention to provide an apparatus and method for capturing and decoding a spread spectrum signal using a single correlator that is directly used, inexpensive and simple to use. It is in. Another object of the present invention is to capture and decode a spread spectrum signal having double threshold detection capability in one correlator for determining the occurrence of a first data symbol or a second data symbol. It is an object of the present invention to provide an apparatus and a method for implementing the method. It is another object of the present invention to provide an apparatus and method for detecting a spread spectrum signal without using a synchronization reference code.
Another object of the present invention is to capture a spread spectrum signal on each data bit received at a rate at which data is transmitted without the use of any code synchronization preamble and without the time wasted due to code synchronization. To provide an apparatus and a method for decryption.

[0007]

According to the present invention, there is provided an apparatus for decoding a spread spectrum signal, comprising the steps of: generating a spread spectrum signal having a data signal modulated by a code having a length of L; An apparatus for decoding, comprising: means for generating a correlation signal for (L / 2 + 1) or more chips of a spread spectrum signal and for (L / 2 + 1) or more chips of a signal corresponding to the code; Means for directly generating a plurality of data symbols in response to comparing the correlation signal with a plurality of threshold levels.

According to a second aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal, wherein the correlation signal is less than L of the spread spectrum signal. It is characterized by being generated for more than 2 + 1) chips.

An apparatus for decoding a spread spectrum signal according to claim 3 of the present invention is an apparatus for decoding a spread spectrum signal having a data signal modulated with a code having a length L. Means for generating a correlation signal for the signal corresponding to the code, and means for directly generating a data signal in response to the correlation signal, wherein the data signal is 1 is provided with one data bit for each of the L chips.

According to a fourth aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal, wherein the apparatus for decoding a spread spectrum signal having a data signal modulated with a code is provided. Signal, means for generating a correlation signal for a signal corresponding to the code, and means for generating a data signal in response to the correlation signal without reference to a code preamble for the code. And

According to a fifth aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal according to the fourth aspect, wherein the means for generating the correlation signal and the means for generating the data signal comprise an elastic surface. And a wave device.

According to a sixth aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal, the apparatus for decoding a spread spectrum signal having a data signal modulated by a code. Means for generating a correlation signal for a signal corresponding to the code, and means for generating a data signal in response to the correlation signal without reference to a synchronization signal for the code. And

According to a seventh aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal according to the sixth aspect, wherein the means for generating the correlation signal and the means for generating the data signal comprise an elastic surface. And a wave device.

An apparatus for decoding a spread spectrum signal according to claim 8 of the present invention is an apparatus for decoding a spread spectrum signal having a data signal modulated by a code, wherein the spread spectrum signal has a data signal modulated by a code. A signal, a means for generating a correlation signal for a signal corresponding to the code, a synchronization signal for the code, and a means for generating a data signal in response to the correlation signal without reference to any of the code preambles And characterized in that:

According to a ninth aspect of the present invention, there is provided an apparatus for decoding a spread spectrum signal according to the eighth aspect, wherein the means for generating the correlation signal and the means for generating the data signal comprise an elastic surface. And a wave device.

According to a tenth aspect of the present invention, there is provided a method for decoding a spread spectrum signal, comprising the steps of: generating a spread spectrum signal having a data signal modulated by a pseudo noise code having a length of L chips; A method for decoding, comprising: receiving and storing a spread spectrum signal; and at least (L / 2 +
1) generating and storing a reference signal corresponding to each of the chips; comparing each chip of the spread spectrum signal with a corresponding chip of the reference signal; Generating a correlation signal representing the degree of coincidence between the first data symbol and the first data symbol in response to comparing the correlation signal with a predetermined first threshold level at a selected clock time. Generating a second data symbol in response to comparing the correlation signal with a predetermined second threshold level at the clock time.

According to the present invention, there is provided a method for decoding a spread spectrum signal, comprising the steps of: generating a spread spectrum signal having a data signal modulated by a pseudo noise code having a length of L chips; A method for decoding, comprising: receiving and storing a spread spectrum signal; and at least (L / 2 +
1) generating and storing a reference signal corresponding to one chip; and generating a plurality of chip comparison signals by adding each chip of the spread spectrum signal to a corresponding chip of the reference signal. Generating a correlation signal by summing the outputs of each of the chip comparison signals; and generating a first data symbol in response to comparing the correlation signal to a first threshold level. , Generating a second data symbol in response to comparing the correlation signal to a second threshold level.

A method for decoding a spread spectrum signal according to claim 12 of the present invention decodes a spread spectrum signal having a data signal modulated by a code having a length of L chips. The (L / 2 + 1) or more chips of the spread spectrum signal are represented by (L / 2 + 1) of the signal corresponding to the code.
Generating a correlation signal by comparing the plurality of chips with one or more chips; and directly generating a plurality of data symbols in response to comparing the correlation signal to a plurality of threshold levels. It is characterized by including.

A method for decoding a spread spectrum signal according to claim 13 is the method according to claim 12, wherein the correlation signal is L of the spread spectrum signal.
It is characterized by being generated for less than but more than (L / 2 + 1) chips.

A method for decoding a spread spectrum signal according to claim 14 of the present invention decodes a spread spectrum signal having a data signal modulated by a code having a length of L chips. Generating a correlation signal for the signal corresponding to the code, and generating a data signal directly in response to the correlation signal, the method comprising: The data signal corresponds to each L in the above code.
One chip is provided with one data bit.

According to a fifteenth aspect of the present invention, there is provided a method for decoding a spread spectrum signal, comprising the steps of: decoding a spread spectrum signal having a data signal modulated by a code having a length of L chips. Generating the correlation signal for the signal corresponding to the code, the synchronization signal for the code, and referring to the code preamble without referring to any of the code preambles. Generating a data signal in response.

A method for decoding a spread spectrum signal according to claim 16 of the present invention is a method for decoding a spread spectrum signal having a data signal modulated by an entire code, the method comprising: A spread signal,
Generating a correlation signal for a signal corresponding to the code; and generating a data signal in response to the correlation signal without referring to a synchronization signal for the code.

A method for decoding a spread spectrum signal according to claim 17 of the present invention is a method for decoding a spread spectrum signal having a data signal modulated by a code, wherein the spread spectrum signal has a data signal modulated by a code. Generating a correlation signal for the signal corresponding to the code; generating a data signal in response to the correlation signal without reference to any of the synchronization signal for the code and the code preamble. And characterized in that:

An apparatus for decoding a spread spectrum signal according to claim 18 of the present invention is an apparatus for decoding a received spread spectrum signal having a data signal modulated with a pseudo noise code. Code register means for storing a pseudo-noise signal, reception sequence storage means for storing the received spread-spectrum signal, and calculating a correlation between the received spread-spectrum signal and the pseudo-noise signal. A correlation means for generating a correlation signal; and responsive to the correlation signal, generating a first data symbol signal when the correlation signal is greater than an upper threshold level, wherein the correlation signal is at a lower threshold. Comparing means for generating a second data symbol signal when the value is smaller than the value level.

According to a nineteenth aspect of the present invention, in the apparatus for decoding a spread spectrum signal according to the eighteenth aspect, the code register means and the reception sequence storage means include a surface acoustic wave device. It is characterized by.

The apparatus for decoding a spread spectrum signal according to claim 20 is the apparatus for decoding a spread spectrum signal according to claim 18, wherein the code register means, the reception sequence storage means, and the correlation means comprise an elastic surface. And a wave device.

According to the invention embodied and broadly described herein, there is provided an apparatus for decoding a received spread spectrum signal comprising a data signal modulated according to a PN code, said apparatus comprising: Threshold setting means;
A first reference sequence storage unit, a reception sequence storage unit, a first correlation unit, and a comparison unit are provided. The first correlation unit may include a first chip comparison unit and a first addition unit. The present invention may further include a second reference sequence storage unit and a second correlation unit. The second correlation means includes a second chip comparison means,
A second adding means may be provided.

The threshold value setting means may set a threshold value for a certain comparison which is equal to or less than the total number of chips per one code to be captured. The threshold value setting means analyzes a pattern and an application of data to be transmitted and / or received by using a spread spectrum signal, a noise environment, and an error correction amount used in the data signal. You may. In response to this analysis, the threshold setting means generates a threshold level. The threshold value setting means may be used to determine each threshold value in advance for a specific device, application, or operating environment, or may be connected to the spread spectrum receiver, and may be connected to the application or operating environment. May be used to set and adjust one or more threshold levels as.

For the case of one correlator having double threshold capability, the first reference sequence storage means stores a first pseudo noise signal and the received sequence storage means stores the received pseudo noise signal. Store the spread spectrum signal. The first chip comparison means connected to the first reference sequence storage means and the reception sequence storage means converts each chip of the received spread spectrum signal to each chip of the first pseudo noise signal. And a plurality of first chip comparison signals are generated. The first addition means connected to the first chip comparison means adds the plurality of first chip comparison signals, thereby generating a first correlation signal. For the implementation of a digital correlator,
In response to the first correlation signal being greater than the upper threshold level, the comparing means generates a first data symbol signal. A first threshold value lower than the lower threshold level;
In response to the correlation signal, the comparing means generates a second data symbol signal.

For an analog correlator implementation, in response to a first correlation signal that is greater than an analog threshold level, the comparing means generates a first data symbol correlation signal. In response to the first inverted correlation signal being greater than the analog threshold level, the comparing means
To generate a data symbol correlation signal.

For the case of two correlators, each having double threshold capability, the first reference sequence storage means stores a first pseudo-noise signal, and the second reference sequence storage means A second pseudo noise signal is stored, and the reception sequence storage unit stores the received spread spectrum signal. The first chip comparison means is connected to the first reference sequence storage means and the reception register means. In response to the received spread spectrum signal, the first chip comparing means compares each chip of the received spread spectrum signal with each chip of the first pseudo noise signal, thereby providing a plurality of chips. First
Is generated. The first adding means is connected to the first chip comparing means. In response to the plurality of first chip comparison signals from the first chip comparison means, the first adding means adds the plurality of first chip comparison signals, thereby providing a first correlation. Generate a signal.

The second chip comparison means is connected to the second reference sequence storage means and the reception sequence storage means. In response to the received spread spectrum signal, the second chip comparing means compares each chip of the received spread spectrum signal with each chip of the second pseudo noise signal, whereby A plurality of second chip comparison signals are generated. The second adding means is connected to the second chip comparing means. In response to the plurality of second chip comparison signals, the second adding means adds the plurality of second chip comparison signals, thereby generating a second correlation signal.

The comparing means is connected to the first adding means and the second adding means. The comparing means when implementing the digital correlator includes an upper threshold level and a lower threshold level for each reference sequence storage means. In response to the first correlation signal being greater than the upper threshold level, the comparing means generates a first data symbol signal. In response to the first correlation signal being less than the lower threshold level, the comparing means
Of the data symbol signal. In response to the second correlation signal being less than the lower threshold level, the comparing means generates a third data symbol signal. A fourth data symbol signal of the comparing means is generated in response to the second correlation signal being greater than the upper threshold level.

In the implementation of the analog correlator, the comparison means includes equal first and second threshold levels for each reference sequence storage means. In response to the first correlation signal being greater than the first threshold level, the comparing means generates a first data symbol signal. In response to the first inverted correlation signal being greater than the second threshold level, the comparing means generates a second data symbol signal. In response to the second inverted correlation signal being greater than the second threshold level, the comparing means generates a third data symbol signal. In response to the second correlation signal being greater than the first threshold level,
The comparing means generates a fourth data symbol signal.

Statistically, the accuracy of the detection depends in part on the setting of the threshold level, which is a function of several variables: on a per data symbol basis. The total number of chips that match the total number of chips to be processed, the error rate and degree of forward error correction in the input signal, and whether the data flow to be processed is continuous or periodic repetition, Whether it is patterned, inserted data, pulse modulated, or random.

The present invention further includes means for calculating a correlation between the received spread spectrum signal using the plurality of pseudo noise signals and a plurality of reference sequence storages for storing the plurality of pseudo noise signals. Means. Thereby, the correlation means generates a plurality of correlation signals depending on the specific received spread spectrum signal. Similarly, the comparing means responds to the plurality of correlation signals and stores one of the DTDC reference sequence storing means.
One of a plurality of data symbol signals is generated in response to the correlation signal crossing a particular threshold level in one of the plurality of data symbol signals.

[0037] Other objects and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention.

[0038]

According to the present invention, the following specific effects are obtained. (1) It is possible to provide an apparatus and method for capturing and decoding a spread spectrum signal that is directly used, inexpensive, and simple in use. (2) An apparatus and a method for capturing and decoding a spread spectrum signal using one correlator can be provided. (3) It is possible to provide an apparatus and a method for capturing and decoding a spread spectrum signal with a capture time of a spread spectrum signal equal to the time of one data bit time period for each data bit. . (4) Data is transmitted without any code synchronization time loss and without the use of a code synchronization preamble or synchronization reference code, and a spread spectrum signal is captured for each data bit received at a predetermined rate. An apparatus and method for performing decoding can be provided. This is neither disclosed nor suggested in the prior art. (5) By providing a plurality of double threshold detection correlators, the symbol rates of transmitted and received data are utilized and without increasing the bit rate of transmitted and received codes. It can be increased without increasing the bandwidth of the frequency spectrum. (6) The symbol rate of the transmitted and received data is
It can be increased by a factor of two, and the number of correlators needed in the receiver is increased to a minimum. (7) The time for acquiring the spread spectrum signal remains constant even when the symbol rate of the transmitted and received data increases.

[0039]

BRIEF DESCRIPTION OF THE DRAWINGS Preferred embodiments of the present invention will be described in detail with reference to the examples illustrated in the accompanying drawings.

The present invention includes an apparatus for transmitting and decoding a received spread spectrum signal having a data signal modulated with a PN code to generate a spread spectrum signal. As shown in FIG. 1, the transmitter comprises a code clock generator 21, a code selector 28,
Code generator 22, code clock divider 23, pulse generator 24, data generator 25, modulo 2 adder 2
6, including a carrier generator 29, and a phase shift keying (PSK) modulator and RF (high frequency) transmitter 27. The code clock generator 21 generates a clock signal supplied to the code generator 22 and the clock divider 23. Using a clock divider 23, the code and data of the transmitter 27 are synchronized with a code clock frequency equal to a multiple of the code length L of the data clock frequency, thereby producing a sequence of length L PN codes. One data bit per bit is allowed. The data clock signal from the code clock divider 23 is supplied to the pulse generator 24 and to the data generator 25. The data generator 25 is a data signal source transmitted to the communication system. The output signal of the pulse generator 24 is supplied to the code generator 22, which generates a PN code which is selected by a code selector 28. The cyclical PN code is then output from the code generator 22 and modulo 2 is added to the data supplied from the data generator 25 by a modulo 2 adder 26. The output of the modulo adder 26 is a PSK modulator and a data signal modulated by the PN code, which is phase shift keyed modulated by the carrier generator 29 in the RF transmitter 27.

FIG. 2 shows an example of the timing of the code and the clock signal shown in FIG. The timing diagram illustrates a code clock signal, a data clock signal that is a code clock signal divided by the code length L, a pulse generator reset signal, and the code signal, the data signal, and the encoded data signal. ing. The code signal generates an encoded data signal when modulo 2 is added to the data signal;
When modulated by an RF carrier, it produces a spread spectrum signal. The transmitted spread spectrum signal is received by the receiver illustrated in FIG.

FIG. 3, on the other hand, illustrates a special embodiment of a single dual threshold detection correlation receiver according to the present invention, which is generally modulated with a PN code. An apparatus for decoding a received spread spectrum signal having a data signal is included. The apparatus includes a threshold unit, a first reference sequence storage unit, a reception sequence storage unit, a first correlation unit, and a comparison unit. The first correlation means may include a first chip comparison means and a first addition means. Referring to FIG. 3, the first reference sequence storage means is realized as a reference register 33,
The receiving sequence storing means is realized as a receiving register 39, the first chip comparing means is realized as a first adder 40, the first adding means is realized as a first adder 41, and the comparing means is a first adder 41. And the second symbol comparators 42 and 43. The threshold setting means is realized as a threshold setting unit 45. The first adder 40 is coupled to the first reference register 33 and the reception register 39. First adder 41 is coupled to first adder 40.

In the exemplary configuration shown in FIG. 3, the count controller 30 is coupled to a code clock generator 31, which is connected to a code generator 32 and a reference register 33. I have. The code generator 32 is also connected to the reference register 33. Code selection circuit 34 is coupled to code generator 32. The count controller 30 controls the length of a special pseudo-noise signal selected by the code selection circuit 34 and detected by the receiver, and transmits a code of length L to the code generator 32 to a first reference register. 3
A signal is output to the code clock generator 31 to be output to the code clock generator 3. The count controller 30 triggers the code clock generator 31, which in turn triggers the code generator 32 and the first reference register 33. The code generator 32 converts the special pseudo noise signal determined by the code selection circuit 34 into a first reference register 33.
Output to The code selection circuit 34 provides a signal to a code generator 32, which allows it to scan through multiple pseudo-noise codes. In operation, a single code can be loaded into the first reference register 33, or in scanning mode, the first reference register 33 stores a code that constantly changes until a match to the received code occurs. Can be loaded periodically.

As also shown in FIG. 3, a product detector 3 in which an RF and IF amplifier 35 is coupled to a local oscillator 37 and a low-pass filter 38
6. The low-pass filter 38 is coupled to a reception register 39 and a clock recovery circuit 46.

In the case of one correlator having double threshold characteristics, the first reference register 33 stores the first pseudo noise signal, and the reception register 39 stores the received spread spectrum signal. The first adder 40 compares each chip of the received spread spectrum signal with each respective chip of the first pseudo noise signal to generate a first plurality of chip comparison signals. The first adder 41 adds a first plurality of chip comparison signals, thereby generating a first correlation signal. In response to the first correlation signal being greater than the upper threshold level, comparator 42 generates a first data symbol signal. In response to the first correlation signal being less than the lower threshold level, the comparator generates a second data symbol signal.

In operation, a received spread spectrum signal having a data signal modulated with a PN code is stored in a reception register 39 and the total length L of the first pseudo noise signal is stored in a first reference register 33. You. Each chip of the received spread spectrum signal is modulo 2 summed by each respective chip of the first reference pseudo noise signal by the first adder 40. This modulo addition of the two signals thereby generates a first plurality of chip comparison signals, which are output from the first adder 40 to the first adder 41.
Sent to The first adder 41 adds a first plurality of signals to generate a first correlation signal.

The first symbol comparator 42 and the second symbol comparator 43 are coupled to the first adder 41. Comparator 4
2, 43 have an upper threshold level and a lower threshold level. In response to the first correlation signal being greater than the upper threshold level, the first symbol comparator 42 generates a first data symbol correlation signal. In response to the first correlation signal being less than the lower threshold level, second symbol comparator 43 generates a second data symbol correlation signal. The data generator 47 thereby generates a first or second data symbol for the first or second data symbol correlation signal, respectively. The first and second data symbol signals are 1-bit and 0-bit data signals, respectively.

The present invention further includes using two or more, up to N, different cyclic sequences, shown in FIG. 4 in an example using two. In this special case, the first code generator 52
And a second code generator 53 each generates a cyclic sequence of differences selected by a code selector 62 for generating a spread spectrum code signal. The code clock generator 51 supplies the code clock to the code generator A 52 and the code generator B 53 and also supplies the code clock to the frequency divider 54. 2 / L division is 2 of that of the code sequence of length L.
A clock signal having a period equal to twice is supplied to a 1/2 frequency divider 56, a two-stage shift register 58, and a data generator 55. Therefore, two data bits per code length L are generated by the data generator 55 and stored in the two-stage shift register 58 in parallel. The frequency divider 56 resets the clock signal per code segment of length L to the sampler 57, the code generator A52, and the pulse generator 59 for resetting the code generator 53.
To supply. Sampler 57 selects two signals from selector 60
The selector 60 outputs four code segments (code A, inverted code A, code B, and inverted code B).
, Which receives the code segment from code generator A52 and code generator B53. The modulated code is then sent from selector 60 to PS
It is sent to the K modulator and RF transmitter 61, where it is PSK modulated in the RF carrier generator 63 of the transmitter.
Transmitting a spread spectrum signal using the circuit of FIG. 4 is a special embodiment of the present invention where the receiver detects the received code of four possible spread spectrums as shown in FIG. This has the advantage that a means can be provided to use only two correlators for The special code is actually two spread spectrum PN codes with a 180 degree phase inversion.

Therefore, the present invention can further include a second reference sequence storing means, a second chip comparing means, and a second adding means. The second reference sequence storage means is realized as a second reference register 73, and stores the second reference sequence.
The chip comparing means is implemented as a second adder 80, and the second adder can be realized as a second adder 81. The second reference register 73 stores a second pseudo signal. The second adder 80 is connected to the second reference register 73.
And the reception register 39.

In the case of the two correlators shown in the drawing, each having a dual threshold characteristic, the first adder 40 converts each chip of the received spread spectrum signal to the first One pseudo-noise signal is compared to each respective chip, thereby generating a first plurality of chip comparison signals. The first adder 41 is coupled to the first adder 40. In response to the first plurality of chip comparison signals from the first adder 40, the first adder 41
Are added to generate a first correlation signal.

The second adder 80 is connected to the second reference register 73 and the reception register 39. In response to the received spread spectrum signal, the second adder 80
Comparing each chip of the received spread spectrum signal with each respective chip of the second pseudo noise signal, thereby generating a second plurality of chip comparison signals. The second adder 81 is coupled to the second adder 80. In response to the second plurality of chip comparison signals, the second adder 81
The plurality of modulo addition signals of
Generate a correlation signal.

In this particular embodiment, the comparing means is realized as a comparing circuit 97. Comparison circuit 97
Has upper and lower threshold levels. The comparison circuit 97 is coupled to the first adder 41 and the second adder 81. First adder 4 greater than its upper threshold level
1 in response to the first correlation signal from
7 generates a first data symbol correlation signal. The first from the adder 41 which is smaller than the lower threshold level.
In response to the correlation signal, the comparison circuit 97 generates a second data symbol correlation signal. In response to the second correlation signal from second adder 81 being greater than the upper threshold level, comparison circuit 97 generates a third data symbol correlation signal. In response to the second correlation signal from the second adder 81 that is smaller than the lower threshold level, the comparison circuit 97 generates a fourth data symbol signal. Data generator 98 generates data symbols corresponding to the data symbol correlation signals received therefrom. The first, second,
The third and fourth data symbol signals represent, for example, data bits 00, 01, 10, and 11.

Although the present invention discloses using either the first correlator as shown in FIG. 3 or the first and second correlators as shown in FIG. 5, the present invention discloses a decoder. Can be extended to those that use multiple correlators to decode multiple data symbol signals.

By using DTDC at the receiver, a code of length L can be used to transmit and receive a number of data symbols equal to twice the number of DTDCs at the receiver. Multiple DTDs
Another advantage of using C is that the rate of data symbols transmitted and received is each additional DTD.
By C, code length L, total code chip rate,
And doubling the bandwidth of the frequency spectrum used, but all remain fixed. Moreover, the time to capture the spread spectrum signal remains fixed, and the system is low cost and simple. The code selection signals can provide signals to a code generator, which allows them to scan through multiple pseudo-noise codes. In operation, a single set of codes can be loaded into the reference register, or in scanning mode, the reference register is loaded periodically with a constantly changing code until a match to the received code occurs. can do.

In the system provided by the present invention, the pseudo noise signal is L × (R _d / S _d ), where R _d is the clock rate of the data to be modulated and S _d is the length L It includes a PN code segment with L bits generated at a clock rate equal to the number of data bits per code segment. For example, if the data rate to be transmitted for one data bit is 100 kHz and the code length L is 100, then the code rate is R _c and L × L
(R _d / S _d ) = (100) × (200 kHz / 1) = 1
Equal to 0.0 MHz. For two data bits per code, the data rate increases to 200 kHz, but the code rate is R _c = (100)
× (200 kHz / 2) = 10 MHz. Thus, the data rate can be increased without making the same increase in code rate. Length L
The number of data symbols generated per code segment is 2 ^sd , where S _d = number of data bits per code segment.

At the transmitter, the start of a length L code segment is synchronously aligned with each data set and is defined by the number of data bits per code segment, which produces 2 ^sd data symbols. For example, it transmits two data bits per code segment, then 2 ^sd = 4 data symbols, represented by 00,01,10,11. If data symbol 1 is transmitted, then code 1 is transmitted. If data symbol 2 is transmitted, then the inverse of code 1 is transmitted. A similar process is performed for data symbol 3 that can use the inverse of code 2 and data symbol 4 that can use the normal code 2. At the receiver, reference code 1 and code 2 segments equal to those at the transmitter are loaded into the storage elements of the two correlators and held in a steady state. The received signal then passes through the correlator, and when the correlation value from correlator 1 exceeds its threshold T, a first data symbol correlation signal is generated. If the correlation value is less than LT, then a second data symbol correlation signal is generated. When the second correlation value is less than its LT, the same result continues for the third data symbol, and the second correlator outputs its T
If so, the fourth data symbol follows.

The second preferred embodiment of the present invention uses an analog device such as a surface acoustic wave device as an example of the analog device, and includes a reference sequence storage device and a reception sequence storage device. The surface acoustic wave device (SAW) further includes an adder 40 and an adder 41.
And functions as a complete self-contained correlator unit. In addition, multiple sets of reference sequence stores are configured on one special surface acoustic wave device in addition to the receive sequence store to provide a very compact means for decoding multiple pseudo-noise signals. You may make it.

A delay line matched to a filter or a SAW correlator is a passive device designed to recognize a particular sequence of code chips, as does a digital correlator, but more than a voltage level at baseband. Rather, it does this through correlation of phase shifts in the RF signal, thus avoiding many of the problems inherent in digital correlators, such as high noise or interference / jamming environments.

Each delay element in the correlator has a delay time equal to the period of the transmitted code clock such that each element corresponds to only one chip at any given time. As the received signal propagates through the delay line, the phase configuration of each element is added in-phase or out-of-phase with the propagated PN coded wave, and the outputs of all elements are added and integrated. Reaches the correlation value of. When the configuration of all phase shifts of the above elements matches the phase shift of the propagating wave, then the maximum sum and correlation is achieved.

In order to achieve the desired correlation, the correct reference code must be "loaded" on the SAW device. This description is for a BPSK device; however, the present invention is directed to MSK, QPS
Covers and encompasses any PSK such as K, etc. Assuming two-phase shift keying, the phase inversion is P
Occurs at each one / zero transition of the N code. This is usually accomplished in one of two ways. The first is by a programmable correlator that can output all phases at each element. As shown in FIG. 6, for a two-phase shift keying device, the count controller 101
And a code clock generator 102 that sends an L clock signal to the reference register 105. Code generator 104
Then generates a unique code determined by the code selector 103 and loads it into the reference register 105. Once the code is stored in the reference register 105, the zero / one pattern is
The contents of the register A (2) connected to (2) are loaded into the delay line correlator 106, and similarly loaded up to the element A (L). The correlator then has all of the outputs of the element corresponding to the first data symbol connected to the adders 108, 110 and the outputs of all the elements corresponding to the second data symbol It is programmed to be connected to the adders 109 and 111. In this example, the first data symbol is implemented as a first phase symbol, and the second data symbol is implemented as a second phase symbol.

In a non-programmable device, these phase shifts are programmed at the time of configuration through transducers located in each element to produce an initial phase match, and cannot be changed by the user, Therefore, only one code sequence can be correlated. The inverting and non-inverting phase elements are then added as in the programmable device above.

PN code, PSK modulation, and SAW
When a signal having an RF frequency equivalent to that at the correlator is received, the received signal is then amplified (and possibly down-converted, if not necessary down-conversion to an intermediate frequency is not preferred, ) Is supplied to the delay line correlator 106. As the wave propagates across the correlator surface, the energy in each delay element increases by a factor determined by the phase of the reference element relative to the phase of the received signal.

The outputs of the delay elements having the same phase as the first phase are added by adders 108 and 110, while those elements which are 180 degrees out of phase with the first phase are added by adders 109 and 111. Is added. A PSK modulated signal having the same PN code phase shift as those referenced in the correlator, which is a non-inverted code segment, propagates through the device and
When the code chip reaches the end of the delay line, all phase shifts of the received signal match those of the element containing the correlator, and the maximum energy of the first phase is obtained. Inverted first phase adder 109
Are inverted by the phase inverter 112 and added in phase with the output of the first adder 108 of the adder 114. If the output of the adder 114 is the threshold setting unit 1
A first data symbol correlation signal is generated by the threshold detector when the threshold value set by the threshold detector is set by the threshold detector and a first data symbol signal is generated; 119.

A PSK modulated signal having the same non-inverted PN code phase shift as those referred to in the correlator, which is an inverted code segment, propagates through the device and the first code chip is Upon reaching the end of the delay line, all phase shifts of the received signal match those of all elements including the correlator, and the maximum energy of the inverted first phase is obtained. The output of the first phase adder 110 is inverted by the phase inverter 113 and added in phase with the inverted output of the first phase adder 111 of the adder 115. If the output of adder 115 exceeds the threshold set in threshold detector 117 by threshold setter 118, a second data symbol correlation signal is generated by threshold detector 117 and Second
Generator 119 for generating a data symbol signal of
Supplied to

The difference between the method and apparatus according to the invention and those used in the prior art is that the correlated pulses are used to derive the data symbols, while other systems use longer reference codes. The use of pulses to synchronize the incoming code signal to the incoming signal.

The difference between SAW devices and digital correlators lies in the frequency band in which they are used. SAW devices are usually employed at intermediate frequencies, but they can also be used at high frequencies. The digital correlator is typically used at baseband. Another difference is that a digital correlator performs a voltage level comparison, whereas a SAW device performs a phase shift comparison. Further, the SAW device adds the output differently than that of a digital correlator. Also, when the invention is implemented with a SAW correlator, no received code clock is required to correlate the PN codes. The present invention using a SAW correlator can be realized using fewer components.

The present invention further includes a method of using a correlator to decode a received PSK spread spectrum signal, wherein the PSK spread spectrum signal includes a data signal modulated with a PN code, Modulated with a high frequency carrier to generate a spread spectrum RF signal. A first method uses the digital correlator, sets upper and lower threshold levels using threshold setting means, stores a pseudo-noise signal in reference sequence storage means, and The spread spectrum signal is stored in the reception sequence storage means, and the received spread spectrum signal is correlated with the pseudo-noise signal to generate a correlation signal, that is, a correlation calculation is performed to convert the correlation signal into an upper threshold level and a lower threshold level. A first data symbol is generated in response to a correlation signal greater than the upper threshold level and in response to a correlation signal greater than the upper threshold level, and a second data symbol is generated in response to a correlation signal less than the lower threshold level. Generating a data symbol.

A second method uses an analog correlator, for example, a SAW correlator, sets two threshold levels that may be equivalent, and uses threshold setting means.
A pseudo-noise signal is stored in a reference sequence storage means, a received spread spectrum signal is stored in a reception sequence storage means, and the spread spectrum signal is correlated with the pseudo-noise signal to generate two correlation signals. Comparing the correlation signal with a first threshold level and comparing the inverted correlation signal with a second threshold level, and responsive to the first correlation signal that is greater than the first threshold level to convert the first data symbol. Generating a second data symbol in response to an inverted correlation signal generated and greater than a second threshold level.

For the present invention, various modifications may be made to an apparatus for decoding a received spread spectrum signal, including a data signal modulated with a spread spectrum, without departing from the scope or spirit of the invention. It will be apparent to those skilled in the art that modifications can be made, and it is intended that the present invention cover modifications and variations of the device that come within the scope of the appended claims and their equivalents. Means.

[Brief description of the drawings]

FIG. 1 is a block diagram of a transmitter according to a first embodiment of the present invention.

FIG. 2 is a timing chart of a specific signal according to the first embodiment.

FIG. 3 is a block diagram of a receiver according to the first embodiment of the present invention.

FIG. 4 is a block diagram of a transmitter according to a second embodiment of the present invention.

FIG. 5 is a block diagram of a receiver according to a second embodiment of the present invention.

FIG. 6 is a block diagram of a SAW correlator which is an analog embodiment used in the present embodiment.

[Explanation of symbols]

 Reference numeral 21: code clock generator, 22: code generator, 23: code clock divider, 24: pulse generator, 25: data generator, 26: modulo 2 adder, 27: PSK modulator and RF transmitter, 28 code selector, 29 carrier generator, 30 count controller, 31 code clock generator, 32 code generator, 33 first reference register, 34 code selector circuit, 35 RF and IF amplifier 36, product detector, 37, local oscillator, 38, low-pass filter, 39, reception register, 40, first adder, 41, first adder, 42, first symbol comparator, 43, second symbol Comparator, 45: Threshold value setting device, 46: Clock recovery circuit, 47: Data generator, 51: Code clock generator, 52: First code generator, 53 ... second code generator, 54 ... frequency divider, 55 ... data generator, 56 ... 1/2 frequency divider, 57 ... sampler, 58 ... two-stage shift register, 59 ... pulse generator, 60 ... selector, 61: PSK modulator and RF transmitter 62: Code selector 63: RF carrier generator 73: Second reference register 80: Second adder 81: Second adder 97: Comparison circuit 98: Data generator 101: Count controller 102: Code clock generator 103: Code selector 104: Code generator 105: Reference register 106: Delay line correlator 108, 109, 110, 111: Addition 112, phase inverter, 113, phase inverter, 114, adder, 115, adder, 116, threshold detector, 117, threshold detector, 118, threshold Joki, 119 ... data generator.

Continuation of the front page (72) Jeffrey S. Inventor.・ Vanderpool United States, Colorado 80915, Colorado Springs, Moccasin Drive No. 2237

Claims (20)

[Claims] 1. An apparatus for decoding a spread spectrum signal having a data signal modulated by a code having a length L, comprising: (L / 2 + 1) or more chips of the spread spectrum signal; Means for generating a correlation signal for (L / 2 + 1) or more chips of a signal corresponding to the code; and, in response to comparing the correlation signal with a plurality of threshold levels, directly converting a plurality of data symbols. Means for decoding a spread spectrum signal, comprising: means for generating a spread spectrum signal; 2. The apparatus of claim 1, wherein the correlation signal is generated for less than L but more than (L / 2 + 1) chips of the spread spectrum signal. 3. An apparatus for decoding a spread spectrum signal having a data signal modulated with a code having a length L, comprising: generating a correlation signal for the spread spectrum signal and a signal corresponding to the code. Means for directly generating a data signal in response to the correlation signal, wherein the data signal comprises one data bit for each of the L chips in the code. An apparatus for decoding a spread spectrum signal that is a feature. 4. An apparatus for decoding a spread spectrum signal having a data signal modulated by a code, comprising: means for generating a correlation signal for the spread spectrum signal and a signal corresponding to the code; Means for generating a data signal in response to the correlation signal without reference to a code preamble for the code. 5. The apparatus according to claim 4, wherein the means for generating the correlation signal and the means for generating the data signal include a surface acoustic wave device. 6. An apparatus for decoding a spread spectrum signal having a data signal modulated by a code, comprising: means for generating a correlation signal for the spread spectrum signal and a signal corresponding to the code; Means for generating a data signal in response to the correlation signal without reference to a synchronization signal for the code. 7. The apparatus according to claim 6, wherein the means for generating the correlation signal and the means for generating the data signal include a surface acoustic wave device. 8. An apparatus for decoding a spread spectrum signal having a data signal modulated with a code, comprising: means for generating a correlation signal for the spread spectrum signal and a signal corresponding to the code; An apparatus for decoding a spread spectrum signal, comprising: a synchronization signal for a code; and a means for generating a data signal in response to the correlation signal without referring to any of the code preambles. . 9. The apparatus according to claim 8, wherein the means for generating the correlation signal and the means for generating the data signal include a surface acoustic wave device. 10. A method for decoding a spread spectrum signal having a data signal modulated over a pseudo-noise code having a length of L chips, comprising: receiving and storing a spread spectrum signal. Generating and storing a reference signal corresponding to at least (L / 2 + 1) chips of the pseudo-noise code; and comparing each chip of the spread spectrum signal with a corresponding chip of the reference signal. Generating a correlation signal indicating the degree of coincidence between the spread spectrum signal and the reference signal; and comparing the correlation signal with a first predetermined threshold level at a selected clock time. Generating a first data symbol in response to the correlation signal and a predetermined second threshold level at the clock time. Method for decoding a spread spectrum signal, characterized in that it comprises a step of generating a second data symbol in response to comparing. 11. A method for decoding a spread spectrum signal having a data signal modulated over a pseudo-noise code having a length of L chips, comprising: receiving and storing a spread spectrum signal. Generating and storing a reference signal corresponding to at least (L / 2 + 1) chips of the pseudo-noise code; and adding each chip of the spread spectrum signal to a corresponding chip of the reference signal. Generating a plurality of chip comparison signals, generating a correlation signal by adding the respective outputs of the chip comparison signals, and comparing the correlation signal with a first threshold level Generating a first data symbol in response to the second signal level and comparing the correlation signal with a second threshold level in response to a second data symbol.
Generating the data symbols of the spread spectrum signal. 12. A method for decoding a spread spectrum signal having a data signal modulated over a code having a length of L chips, comprising: (L / 2 + 1) number of said spread spectrum signals. Generating a correlation signal by comparing the above chip with (L / 2 + 1) or more chips of a signal corresponding to the code; and comparing the correlation signal with a plurality of threshold levels. Generating the plurality of data symbols directly in response to the spread spectrum signal. 13. The method of claim 12, wherein the correlation signal is generated for less than L but more than (L / 2 + 1) chips of the spread spectrum signal. 14. A method for decoding a spread spectrum signal having a data signal modulated over a code having a length of L chips, the method corresponding to the spread spectrum signal and the code. Generating a correlation signal for the signal; and directly generating a data signal in response to the correlation signal, wherein the data signal comprises one bit of data for each L chips in the code. A method for decoding a spread spectrum signal comprising bits. 15. A method for decoding a spread spectrum signal having a data signal modulated with a code having a length of L chips, the method comprising decoding the spread spectrum signal and a signal corresponding to the code. Generating a correlation signal; a synchronization signal for the code; and generating a data signal in response to the correlation signal without reference to any of the code preambles. A method for decoding a signal. 16. A method for decoding a spread spectrum signal having a data signal modulated over a code, the method comprising: generating a correlation signal for the spread spectrum signal and a signal corresponding to the code; Generating a data signal in response to the correlation signal without reference to a synchronization signal for the code. 17. A method for decoding a spread spectrum signal having a data signal modulated with a code, the method comprising: generating a correlation signal for the spread spectrum signal and a signal corresponding to the code; A method for decoding a spread spectrum signal, comprising: synchronizing a signal for a code; and generating a data signal in response to the correlation signal without reference to any of the code preambles. 18. An apparatus for decoding a received spread spectrum signal having a data signal modulated with a pseudo noise code, said code register means storing a pseudo noise signal; and said received spread spectrum signal. A reception sequence storage unit for storing a signal; a correlation unit that calculates a correlation between the received spread spectrum signal and the pseudo noise signal to generate a correlation signal; Comparing means for generating a first data symbol signal when the correlation signal is larger than an upper threshold level, and generating a second data symbol signal when the correlation signal is smaller than a lower threshold level; An apparatus for decoding a spread spectrum signal, comprising: 19. The apparatus according to claim 18, wherein said code register means and said reception sequence storage means include a surface acoustic wave device. 20. The apparatus according to claim 18, wherein said code register means, said reception sequence storage means, and said correlation means include a surface acoustic wave device.