CN1165123C - Signal treatment method of underwater sound coherent communication system with high code speed and low error probability - Google Patents

Abstract

The present invention relates to an underwater sound coherent communication system which is used for transmitting instructions, data and images under water and has high code velocity and low bit error probability, and an underwater sound coherent communication signal processing method. The communication system comprises a host machine and a slave machine, wherein the host machine is installed on a mother ship or a main-control underwater carrier A, and comprises an electronic branch machine, a transmitting transducer and a receiving line matrix which is perpendicularly suspended in water and is composed of more than two hydrophones. The slave machine is installed on an underwater carrier B, and comprises an electronic branch machine and a receiving and sending transducer. The underwater sound coherent communication signal processing method of the present invention uses a signal processing method combining a space diversity technology, a self-optimal self-adaptive decision feedback equalizer and a self-optimal self-adaptive phase tracker to work; the method overcomes the influence of communication channels and carrier motion, makes received signals very approach to transmitting signals, and has low bit error probability.

Description

The signal processing method of the underwater sound coherent communication system of high code speed and low error probability

Technical field

The present invention relates to a kind of water sound communication technique, particularly relate to a kind of underwater sound coherent communication system of using high bit rate, the low level probability of error and carry out method for processing signals.

Background technology

Underwater sound coherent communication system and signal processing method are summarized as follows at present:

(1) method and instrument multichannel combined and balanced in the multichannel receiver have for example been introduced in people's such as J.G.Proakis the United States Patent (USP) 5844951 " Method and apparatus forsimultaneous beam forming and equalization ".Receiver is realized diversity associating, balanced and synchronous simultaneously.The self-adapting multi-channel receiver that the method for this invention and instrument provide the complexity that is used for Underwater Acoustic Digital Communication System to simplify.The content of this invention mainly is the receiver of underwater sound coherent communication system, sees Fig. 1, mainly contains the invention of three aspects, is described below:

(A) multichannel receiver, the implementation space diversity has 1......K passage in Fig. 1.

(B) decision-feedback adaptive equalizer (DFE), a among Fig. 1 ₁(n) ... a _k(n) passage is the leading portion of equalizer, and b (n) is the equalizer feedback section.Adopt stable recurrence least square (RLS) method of Fast numerical to realize adaptive equalization.

(C) phase tracker is realized signal Synchronization, the p among Fig. 1 ₁(n) ... p _k(n) be phase tracker.Adopt the method for second-order PLL (DPLL) to realize Phase Tracking.

(2) introduced the instrument under water that transmits and receives high data rate and speech communication in people's such as M.Sonnenschein the United States Patent (USP) 6130859 " Method and apparatus forcarrying out high data rate and voice underwater communication ", it comprises 1. 1 transmitters; 2. receiver; 3. Doppler shift compensation device.One frequency in two unmodulated signals of Doppler shift compensation device measurement, this unmodulated signal is launched as the signal part of modulation, and frequency and the frequency preset that records compared, and tries to achieve Doppler frequency shift.

Have 3 major defects in the present existing underwater sound coherent communication technology, (1) they can not fast detecting and the phase place of tracking signal, so the phase place of equalizer coefficients rotates, equalizer lost efficacy sometimes.Adopt second-order PLL detection and tracking signal phase in the United States Patent (USP) 5844951, because two coefficients wherein determine that it can not adapt to the quick time varying characteristic of underwater acoustic channel.When the movement velocity of interface, water body and the carrier etc. of channel surpassed 0.14m/s, second-order PLL promptly lost efficacy.Once launch in two unmodulated signals in the United States Patent (USP) 6130859 at least, try to achieve Doppler frequency shift, this is the average Doppler frequency shift in this time launching.The underwater acoustic channel that becomes when quick is not enough to the tracking signal phase place.Broadband signal is not enough to represent movement velocity.(2) adopted the stable recurrence least square of Fast numerical (RLS) method to realize that experiment shows that when the channel more complicated, it does not catch up with the variation of channel from suitable balanced in the United States Patent (USP) 5844951, equalizer lost efficacy.(3) number of the suitable certainly equalizer coefficients in the United States Patent (USP) 5844951 is several ten, the computing more complicated, during realization to the requirement of hardware than higher.

Summary of the invention

Purpose of the present invention: (1) can not fast detecting and the defective of the phase place of tracking signal in order to solve existing underwater sound coherent communicator and signal processing method; (2) two of purpose be to solve adaptive decision feedback equalizer in existing underwater sound communication device and the signal processing method and can not follow the tracks of the signal that underwater acoustic channel causes apace and change; (3) three of purpose to be to solve the number of existing adaptive decision feedback equalizer coefficient more, makes the shortcoming of hardware more complicated; (4) four of purpose in order to overcome many ways effect in the water; Thereby provide a kind of underwater sound coherent communication system and underwater sound coherent signal of communication processing method with high bit rate, low level probability of error.

The object of the present invention is achieved like this: signal processing method provided by the invention is to be applied in high bit rate, the low level probability of error underwater sound coherent communication system of transfer instruction, data and image under water, this system comprise one by transmitting transducer, hang on the slave that transducer that main frame that reception linear array in the water and electronics extension set form and one share by transmitting-receiving and electronics extension set are formed; Wherein main frame is installed in lash ship or master control under water on the carrier A, transmitting transducer and receive linear array from lash ship or master control under water carrier A be hanging to the water, the cable of transmitting transducer and reception linear array respectively with the electronics extension set in transmitter be connected with multichannel receiver; Slave is installed under water on the carrier B, and transmitting-receiving is share transducer and is directly installed under water on the carrier B, and the transmitter and receiver in the electronics extension set of its cable and slave is connected; It is characterized in that: the centre frequency of this system is between 7k～45kHz, and bandwidth of operation is between 5k～20kHz; Reception linear array in the described main frame is made up of 2～16 hydrophones, hang in the water, spacing between the adjacent hydrophone is between 8～40 wavelength, and each hydrophone is non-directive in the horizontal direction, and the working band requirement of this system's regulation is satisfied in the receiving sensitivity frequency response.

Transmitting-receiving in described transmitting transducer or the slave is share transducer and is included directional transducer, and its wave beam angle of release is 60～120 degree.Or be included in the horizontal direction non-directive.

Described main frame comprises: transmitting transducer, vertical hanging reception linear array (being called space diversity reception to communicate) and electronics extension set of being made up of 2 above hydrophones in water, the electronics extension set comprises transmitter, multipath receiver, multi-channel data acquisition device, high speed digital signal processor, input/output interface and main control computer.Main frame is installed in lash ship or master control under water on the carrier A, transmitting transducer and receive linear array from lash ship or master control under water carrier A be hanging to the water, transmitting transducer and the cable that receives linear array respectively with the electronics extension set in transmitter be connected with multichannel receiver, receiver is electrically connected with the multi-channel data acquisition device, the multi-channel data acquisition device is electrically connected with high speed digital signal processor, high speed digital signal processor is electrically connected with the main control computer that has hard disk, and input/output interface and main control computer, transmitter, multichannel receiver electrically connect (seeing accompanying drawing 3).

The electronics extension set of described main frame comprises transmitter, multipath receiver, multi-channel data acquisition device, high speed digital signal processor, input/output interface and main control computer: wherein the input port of transmitter is connected with main control computer by input/output interface, and the transmitter output port is connected with the transmitting transducer input port.Input/output interface is electrically connected with multipath receiver, high speed digital signal processor respectively, high speed digital signal processor is electrically connected with the multi-channel data acquisition device, the signal of receiving hydrophone linear array inputs to multipath receiver, input to the multi-channel data acquisition device again, transmitting transducer and hydrophone linear array are hung in the water by load-bearing cable and weight, are connected on the electronics extension set by cable.

Described slave comprises: a transducer and the electronics extension set that transmitting-receiving is share, the electronics extension set comprises transmitter, No. one receiver, data acquisition unit, high speed digital signal processor, input/output interface and main control computer.Slave is installed under water on the carrier B, and transmitting-receiving is share transducer and is directly installed under water on the carrier B, and the transmitter and receiver in the electronics extension set of its cable and slave is connected.Its connecting mode is main frame (accompanying drawing 4) roughly the same.

The electronics extension set of described slave comprises transmitter, No. one receiver, data acquisition unit, high speed digital signal processor, input/output interface and main control computer; Wherein transmitting-receiving is share transducer and is electrically connected with receiver, transmitter respectively, the output port of No. one receiver is electrically connected with high speed digital signal processor by data acquisition unit, 2 output interfaces of input/output interface connect transmitter, No. one receiver respectively, and input/output interface also is connected with high speed digital signal processor and main control computer respectively; Described electronics extension set is placed on the emission ship, and transmitting-receiving is share transducer and hung in the water by load-bearing cable and weight, is connected to by cable on the electronics extension set of slave.

It can be non-direction in the horizontal direction that transducer is share in transmitting transducer in the described main frame and the transmitting-receiving in the slave, also can be (general wave beam angular width is 60 ~ 120 degree) that directive property is arranged.

The reception linear array of described main frame is made up of 2 ~ 16 hydrophones, and vertical hanging is in water, and the spacing of hydrophone is generally between 8 ~ 40 wavelength.This is called space diversity reception to communicate.Each hydrophone is non-directive in the horizontal direction.

Transmitter in described main frame and the slave is worked under program control, and the startup that program controls transmitter by input/output interface, the waveform that stops and launching, the highpowerpulse signal of output drive transducer and launch sound wave in water.The power output of transmitter is not less than 5W.

Multipath receiver in the described main frame is made up of 2～16 passage receivers, and each passage and 1 hydrophone link.Receiver in the described slave is a single-channel receiver, share transducer with transmitting-receiving and is connected.The working band requirement of claim 2 regulation is satisfied in the frequency response of each passage.Each passage has the gain that is not less than 40dB, has band pass filter with noise and interference beyond the filtering working band, and has AGC control.Automatic gain control can realize with feedback circuit, also can realize by the software feedback, by the software analysis signal amplitude, calculates feedback quantity, gains by the input/output interface adjustment.Receiver can adopt the quadrature mixting circuit, and the baseband signal of output orthogonal also can not done mixing, directly exports CF signal.The amplitude of output signal will be fit to the requirement of multi-channel data acquisition device.

Multi-channel data acquisition device in the described main frame is mainly used in the echo-signal after handling through receiver is carried out data acquisition, its port number is no less than the receiver channel number, the sampling rate of each passage is not less than 4 times of receiver output signal bandwidth, and the figure place of AD converter is not less than 10.

The sampling rate of the data acquisition unit in the described slave is not less than 4 times of receiver output signal bandwidth, and the figure place of AD converter is not less than 10.

High speed digital signal processor in the described main frame is used for digitized echo-signal is handled in real time, recovers the information that it carries according to space diversity, multi-channel adaptive DFF with from optimal self-adaptive phase tracker united signal processing method from echo.Require its disposal ability to be not less than 400MIPS, ram space is not less than the 256k byte, and the data pass rate between the multi-channel data acquisition device is not hanged down the output data rate of multi-channel data acquisition device.

High speed digital signal processor in the described slave is used for digitized echo-signal is handled in real time, recovers the information that it carries according to adaptive decision feedback equalizer with from optimal self-adaptive phase tracker united signal processing method from echo.Require its disposal ability to be not less than 33MIPS, ram space is not less than the 128k byte, and the data pass rate between the data acquisition unit is not less than the output data rate of data acquisition unit.

Input/output interface in described main frame and the slave is used for electronics extension set main control computer and the high speed digital signal processor digital and analog signaling interface to parts such as receiver, transmitter, power supply, wake-up circuits, require to have at least DA output more than 1 tunnel, the DA output resolution ratio is not less than 10, renewal rate is not less than 30k SPS, is used to export the transmitter that transmits signals to of multiple phase shift keying (MPSK) modulation.

Described underwater sound coherent signal of communication processing method is space diversity, from the optimal self-adaptive DFF with from optimal self-adaptive phase tracker united signal processing method, see patent accompanying drawing 1 based on the coherent receiver of self-adapting multi-channel DFF (DFE) accordingly.Should be similar to United States Patent (USP) 5844951 based on the coherent receiver form of self-adapting multi-channel DFF (DFE), it is characterized in that the multi-channel adaptive DFF adopts quick self-optimizing least mean-square error (FOLMS) method, its gain factor u adopts LMS method self adaptation to adjust; From the optimal self-adaptive tracker signal of a plurality of passages is carried out phase compensation respectively, adopt quick self-optimizing least mean-square error (FOLMS) method, its gain factor λ adopts LMS method self adaptation to adjust.

Application high code speed and low error probability underwater sound coherent communication system provided by the invention carries out the underwater sound coherent method for processing signals, comprises the processing procedure of emission process, receiving course and the received signal of signal; Wherein the emission process of signal comprises: main frame/slave is at first modulated data to be sent, and the data after the modulation are delivered to transmitter through IOC, and transmitter drives transmitting transducer/transmitting-receiving and share transducer emission sound wave; Wherein the receiving course of main frame comprises: the slave emitting sound wave is at water transmission, each hydrophone of the reception linear array of main frame converts the acoustic signals that receives to the signal of telecommunication multipath receiver of feeding, and multipath receiver is handled after the multi-channel data acquisition device becomes digital signal; Wherein the receiving course of slave comprises: the main frame emitting sound wave is at water transmission, and the transmitting-receiving of slave is share transducer the acoustic signals that receives is converted to the signal of telecommunication receiver of feeding, and receiver is handled after data acquisition unit becomes digital signal; Wherein the processing procedure of received signal comprises: digitized received signal is handled in high speed digital signal processor, and the result of acquisition exists in the hard disk, perhaps delivers in other terminal equipment via serial port; It is characterized in that: the data-modulated mode of emission process is the multiple phase shift keying modulation; The receiving course of main frame adopts reception linear array, multipath receiver and the multi-channel data acquisition device with a plurality of hydrophones, implementation space diversity; Processing procedure adopts space diversity, multi-channel adaptive DFF and from optimal self-adaptive phase tracker united signal processing method, wherein the multi-channel adaptive DFF adopts quick self-optimizing least mean-square error method, and its gain factor μ adopts least mean-square error (LMS) method self adaptation to adjust; From the optimal self-adaptive phase tracker signal of a plurality of passages is carried out phase compensation respectively, adopt quick self-optimizing least mean-square error method, its gain factor λ adopts least mean-square error (LMS) method self adaptation to adjust.

The transmission workflow of described high bit rate, low level probability of error underwater sound coherent communication system main frame and slave is as follows:

Main control computer is given high speed digital signal processor transfer of data to be sent, by high speed digital signal processor pack tissue, coding, modulation, produce digitized waveform, DA by input/output interface outputs to transmitter then, carry out power amplification by transmitter, produce high-power multiple phase shift keying (MPSK) electric impulse signal and drive transmitting transducer, convert ping and Xiang Shuizhong emission to.

The reception workflow of described high bit rate, low level probability of error underwater sound coherent communication system main frame and slave is as follows:

The other side's emitting sound wave signal is share transducer by the transmitting-receiving of the reception linear array of main frame or slave and receives, and the signal of receiving becomes digital signal by data acquisition unit with it after receiver is handled; Digital signal is imported into high speed digital signal processor, and high speed digital signal processor will be handled digital signal, and result is imported in the computer, and is kept on the hard disk, also can output in other terminal equipment through serial port.

The workflow of described high bit rate, low level probability of error underwater sound coherent communication system is as follows:

Communication between main frame and the slave is half-duplex mode, begins communication process by main frame.Main frame at first sends a wake-up signal, waits for replying of slave then.As do not receive to reply and then repeat this process.Slave is under the low power consumpting state, after its wake-up circuit receives wake-up signal, activates other circuit of slave, after slave enters normal operating conditions, sends an answer signal to main frame.When slave does not have wake-up circuit, receive wake-up signal after, also send an answer signal to main frame.What main frame received slave replying the back data waiting for transmission pack tissue, coding, modulation and launch, and slave reception sound wave is handled in real time, recovers the data of main frame transmission.After main frame sent and finishes, slave carried out transfer of data to main frame.Slave is launched data waiting for transmission pack tissue, coding, modulation then, and main frame is in accepting state all the time when not launching, receive the acoustic signals of slave after, handle in real time, recover the data that slave sends.

The invention has the advantages that: (1) owing to use and of the present inventionly underwater acoustic channel to be regarded as at time-delay territory and the double diffused model of frequency domain when being used for high bit rate, low level probability of error underwater sound coherent communication system and signal processing method and carrying out work, thinks that the phase place of underwater sound signal is-fast-changing random quantity.Of the present invention from the optimal self-adaptive phase tracker in Fig. 1 with p ₁(n)-p _k(n) expression, it is-adopt the phase estimating device of lowest mean square (LMS) method, the LMS method is applicable to the estimation of random quantity.Being different from the general LMS method gain factor γ is regarded as the amount of determining, among the present invention the γ in the LMS method is regarded as random quantity, adopt the LMS method to estimate again to γ, also is that the γ value can be selected from optimum value voluntarily.Above-mentioned showing, in the optimal self-adaptive phase tracker, adopted dual LMS method of the present invention, so it can follow the tracks of fast-changing random quantity, i.e. the phase place of signal.

(2), think that the amplitude of underwater sound signal is-fast-changing random quantity owing to use and of the present inventionly underwater acoustic channel to be regarded as time-delay territory and the double diffused model of frequency domain when being used for high bit rate, low level probability of error underwater sound coherent communication system and signal processing method and carrying out work.Of the present invention from the optimal self-adaptive DFF in Fig. 1 with a ₁(n) ... a ₂(n) and b (n) expression, its adopts lowest mean square (LMS) method to carry out the self adaptation computing.Being different from the general LMS method gain factor μ is regarded as the amount of determining, among the present invention the LMS method is carried out the self adaptation computing, also is that the μ value can be selected optimum value voluntarily.Above-mentioned showing, in the optimal self-adaptive DFF, adopted dual LMS method of the present invention, so it can follow the tracks of fast-changing random quantity, i.e. the amplitude of signal.

(3) owing to use full lowest mean square (LMS) method that adopts when being used for high bit rate, low level probability of error underwater sound coherent communication system and signal processing method and carrying out work of the present invention, compare with the RLS method, the LMS method is simple, and operand is little.Again owing to adopt dual LMS method, from the optimal self-adaptive phase estimating device and from the exponent number of optimal self-adaptive DFF less than 11.

(4), on a plurality of distances, carry out the underwater sound communication test because the present invention uses high bit rate, low level probability of error underwater sound coherent communication system to carry out method for processing signals and tests, and main frame and slave respectively are contained on the ship on the several lake.The most complicated at 2000 meters channels of distance, test data analyzer the results are shown in Figure 12 and Figure 13.Figure 12 is space diversity of the present invention, from optimal self-adaptive DFF and the result that obtains from the optimal self-adaptive phase tracker, bit error probability 1.9 * 10 ^-5Be the result that stable recurrence least square (RLS) of space diversity, Fast numerical in the United States Patent (USP) 5844951 and second-order PLL algorithm obtain among Figure 13, the bit error probability is 1.95 * 10 ^-2Result of the present invention is significantly better than the result in the United States Patent (USP) 5844951.

(5) result of the test is seen Figure 14.As seen from the figure, when speed of related movement less than when equaling 1.4m/s, the bit error probability still can remain 10 ^-5This result is significantly better than the 0.14m/s in the United States Patent (USP) 5844951.

(6) result of the test on a plurality of distances is seen Figure 15.As seen from the figure, receive image and do not see significant difference with the transmission image.At the 4000m place, transmission rate 10kbits/s, the bit error probability is better than 10 ^-4Obtain operating distance transmission rate=40kmkbits/s thus.Reach the upper limit of the world level of 20th century late nineteen nineties in the world, seen Figure 16.Curve is the upper limit among the figure, and the * on the curve is result of the present invention.

Description of drawings

Fig. 1 is based on the coherent receiver of self-adapting multi-channel DFF (DFE)

Fig. 2 underwater sound coherent communication system work of the present invention schematic diagram

Fig. 3 underwater sound coherent communication system main frame of the present invention block diagram.

Fig. 4 underwater sound coherent communication system slave of the present invention block diagram.

The transmitter circuitry block diagram of Fig. 5 underwater sound coherent communication system of the present invention

The circuit block diagram of a passage of receiver of Fig. 6 underwater sound coherent communication system of the present invention

Fig. 7 underwater sound coherent communication system multichannel collecting of the present invention device block diagram

Fig. 8 underwater sound coherent communication system high speed digital signal processor of the present invention circuit block diagram

Fig. 9 underwater sound coherent communication system input/output interface of the present invention block diagram

Figure 10 underwater sound coherent communication system wake-up circuit of the present invention block diagram

Figure 11 a underwater sound coherent communication system emission of the present invention software flow pattern

Figure 11 b underwater sound coherent communication system receiving software of the present invention flow chart

Figure 11 underwater sound coherent communication system software flow pattern

The gain factor γ of LMS estimator is with the variation of symbolic number in Figure 12 (a) phase tracker of the present invention

The gain factor μ of LMS estimator is with the variation of symbolic number in Figure 12 (b) adaptive equalizer of the present invention

Mean square error (MSE) in Figure 12 (c) analysis result of the present invention is with the variation of symbolic number

3 channel phases in Figure 12 (d) analysis result of the present invention are estimated the variation with symbolic number

System's output planisphere in Figure 12 (e) analysis result of the present invention

Symbol error in Figure 12 (f) analysis result of the present invention distributes

Figure 12 space diversity of the present invention, from the optimal self-adaptive DFF with from the test data analyzer result of optimal self-adaptive phase tracker algorithm when channel is the most complicated, signal is QPSK, transmission rate 10kbits/s, operating distance is 2000m, bit error probability 1.90 * 10 ^-5Equalizer coefficients exponent number [a ₁a ₂a ₃B]=[1; 1; 1; 11].

Mean square error (MSE) in U.S. patent 5844951 analysis results of Figure 13 (a) is with the variation of symbolic number

System's 3 channel phases in U.S. patent 5844951 analysis results of Figure 13 (b) are estimated the variation with symbolic number

System's output planisphere in the analysis result of the U.S. patent 5844951 of Figure 13 (c)

Symbol error in the analysis result of the U.S. patent 5844951 of Figure 13 (d) distributes

The stable recurrence least square (RLS) and the test data analyzer result of second-order PLL algorithm when channel is the most complicated of space diversity, Fast numerical of the U.S. patent 5844951 of Figure 13, signal is QPSK, transmission rate 10kbits/s, operating distance is 2000m, bit error probability 1.95 * 10 ^-2Equalizer coefficients number [a ₁a ₂a ₃B]=[2; 2; 2; 12].

Mean square error (MSE) among Figure 14 (a) simulation analysis result of the present invention is with the variation of symbolic number

Planisphere among Figure 14 (b) simulation analysis result of the present invention

Symbol phase among Figure 14 (c) simulation analysis result of the present invention is with the variation of symbolic number

Symbol error among Figure 14 (d) simulation analysis result of the present invention distributes

Figure 14 space diversity of the present invention, from the optimal self-adaptive DFF with from the simulation analysis result of optimal self-adaptive phase tracker algorithm, signal is QPSK, transfer rate 10kbits/s, signal to noise ratio 15dB, relative velocity 1.4 meter per seconds, bit error probability 10 ^-5

Figure 15 uses the comparison that system of the present invention receives the source figure of image and transmission, does not see significant difference among the figure

The index (distance * operating distance) and the upper limit that the existing in the world underwater sound communication system of Figure 16 can reach, the upper limit is by curve representation.* on the curve number is the index that China reaches.

Testing equipment lays figure on the lake of Figure 17 one embodiment of the invention; A left side: emission ship, the right side: taken-over vessel.

The gain factor γ of LMS estimator is with the variation of symbolic number in Figure 18 (a) adaptive Phase track device of the present invention

The gain factor μ of LMS estimator is with the variation of symbolic number in Figure 18 (b) adaptive equalizer of the present invention

Mean square error (MSE) in Figure 18 (c) analysis result of the present invention is with the variation of symbolic number

3 channel phases in Figure 18 (d) analysis result of the present invention are estimated the variation with symbolic number

Output planisphere in Figure 18 (e) analysis result of the present invention

Symbol error in Figure 18 (f) analysis result of the present invention distributes

Figure 18 space diversity of the present invention, from the optimal self-adaptive DFF and from optimal self-adaptive phase tracker algorithm to the test data analyzer result, signal is QPSK, transmission rate 10kbits/s, operating distance is 4000m, bit error probability 1.75 * 10 ^-5Equalizer coefficients exponent number [a ₁a ₂a ₃B]=[2; 2; 2; 9].

Mean square error (MSE) in the analysis result of the U.S. patent 5844951 of Figure 19 (a) is with the variation of symbolic number

Channel phases in the analysis result of the U.S. patent 5844951 of Figure 19 (b) is estimated the variation with symbolic number

Output planisphere in the analysis result of the U.S. patent 5844951 of Figure 19 (c)

Symbol error in the analysis result of the U.S. patent 5844951 of Figure 19 (d) distributes

Recurrence least square (RLS) that space diversity, the Fast numerical of the U.S. patent 5844951 of Figure 19 is stable and second-order PLL algorithm are to the test data analyzer result, and signal is QPSK, transmission rate 10kbits/s, and operating distance is 4000m, bit error probability 2.15 * 10 ^-2

Drawing is described as follows:

1. lash ship or the master control electronics extension set of carrier A 2. main frames under water

3. transmitting transducer 4. receiving hydrophone battle arrays 5. cables

6. load-bearing cable 7. weight 8.MPSK signals

9.MPSK signal 10. is the electronics extension set of carrier B 11. slaves under water

12. transducer 13. emission ships (carrier B under the Simulated Water) are share in transmitting-receiving

14. non-directive emission transducing 15. non-directive receiving hydrophone linear arrays

16. transducer is share in the transmitting-receiving of load-bearing cable 17. cables 18. non-directives

19. weight 20.21. anchor 22. water-bed 23. waters surface

Embodiment

Embodiment 1

Make-be used for the underwater sound coherent communication system of high bit rate, the low level probability of error according to Fig. 1, Fig. 2 and Fig. 3, on certain lake, test.Test lays figure and sees Figure 17 on the lake, and this system comprises the main frame that is installed on the lash ship 1 and is installed in slave on the emission ship 13.The emission ship model is intended carrier B under water, is equivalent to 10 among Fig. 2.

The block diagram of main frame is seen Fig. 3.The electronics extension set 2 of main frame is placed on the lash ship 1, and receiving hydrophone battle array 15 is made up of three horizontal non-directive hydrophones, and the spacing between the adjacent hydrophone is about 10 wavelength.Horizontal non-directive transmitting transducer 14 and hydrophone linear array 15 are hung in the water by load-bearing cable 6 and weight 7, are connected on the electronics extension set 2 by cable 5.

The block diagram of slave is seen Fig. 4.The electronics extension set 11 of slave is placed on the emission ship 13, and the non-directive transmitting-receiving is share transducer 18 and hung in the water by load-bearing cable 16 and weight 19, is connected to by cable 17 on the electronics extension set 11 of slave.

The transmitter of main frame and slave is electrically connected composition (block diagram is seen Fig. 5) by conversion of signals, driving stage, power stage, transformer in proper order by the signal trend, and except that transformer, other all can be by buying on the domestic and international market.Transformer adopting boxlike Ferrite Material, no-load voltage ratio is according to determining with the requirement of transducer impedance coupling.

Fig. 6 is the circuit block diagram of a passage of receiver of main frame and slave, put before it comprises, automatic gain control (AGC) circuit, band pass filter (BPF), quadrature mixing, low pass filter and buffering amplifier, be electrically connected to form in proper order by the signal trend of Fig. 6 circuit; Parts among Fig. 6 in each square frame are special chips, and the domestic and international market all can be buied.

Fig. 7 is the block diagram of multi-channel data acquisition device, it comprises analog input, multiway analog switch (model is MAX308), A/D converter (model is AD1671), FIFO memory (model is IDT7204), logic control circuit, clock generator, main control computer bus and DSP expansion bus, is electrically connected to form in proper order by the signal trend among Fig. 7.

Fig. 8 is the high speed digital signal processor block diagram, it comprises digital signal processing chip (model is TMS320C30), dual port RAM (model is IDT7024), static RAM (SRAM) (SRAM), logic controller and expansion bus, is electrically connected composition in proper order by the signal trend among Fig. 8.

Fig. 9 is the input/output interface circuit block diagram, it comprises digital output interface, digital input interface, timer (model is 8254), D/A converter (model is AD7245A), logic controller and main control computer interface, is electrically connected to form in proper order by the signal trend among Fig. 9.

Figure 10 is the wake-up circuit block diagram, and it comprises a narrow-band amplifier and a phase-locked loop, is electrically connected to form in proper order by the signal trend among Figure 10.

Various digit chips among Fig. 7,8,9 and 10 are general-purpose chip, and at home and abroad market is buied.

The centre frequency of system is 17.5kHz, and bandwidth is 5kHz, and the signal modulation system is MPSK, and wake-up signal is the pure-tone pulse of 13kHz.

Figure 11 a is the flow chart of underwater sound coherent communication system emission software, and Figure 11 b is the notes journey figure of receiving software.

Main control computer is given high speed digital signal processor transfer of data to be sent during emission, by high speed digital signal processor pack tissue, coding, modulation, produce digitized waveform, DA by input/output interface outputs to transmitter then, carry out power amplification by transmitter, transducer 12 is share in the transmitting-receiving that produces high-power multiple phase shift keying (MPSK) electric impulse signal driving transmitting transducer 3 or slave, converts ping and Xiang Shuizhong emission to.

The other side's emitting sound wave signal is share transducer 12 receptions by the transmitting-receiving of the reception linear array 4 of main frame or slave during reception, and the signal of receiving becomes digital signal by data acquisition unit with it after receiver is handled; Digital signal is imported into high speed digital signal processor, and high speed digital signal processor will be handled digital signal, and result is imported in the computer, and is kept on the hard disk, also can output in other terminal equipment through serial port.

Communication between main frame and the slave is half-duplex mode, begins communication process by main frame.Main frame at first sends a wake-up signal, waits for replying of slave then.As do not receive to reply and then repeat this process.Slave is under the low power consumpting state, after its wake-up circuit receives wake-up signal, activates other circuit of slave, after slave enters normal operating conditions, sends an answer signal to main frame.What main frame received slave replying the back data waiting for transmission pack tissue, coding, modulation and launch, and slave reception sound wave is handled in real time, recovers the data of main frame transmission.After main frame sent and finishes, slave carried out transfer of data to main frame.Slave is launched data waiting for transmission pack tissue, coding, modulation then, and main frame is in accepting state all the time when not launching, receive the acoustic signals of slave after, handle in real time, recover the data that slave sends.

With space diversity of the present invention, from the optimal self-adaptive DFF with from optimal self-adaptive phase tracker Figure 12 that the results are shown in to experimental data processing.By Figure 12 (a) as seen, the present invention gain factor γ of being used for the LMS estimator of phase tracker reaches an order of magnitude three passage differences.Therefore adopt second order digital phase-locked loop to be difficult to the quick variation of detection and tracking underwater sound signal phase place in the United States Patent (USP) 5844951 with two preset parameters.Can see by Figure 12 (b), the present invention is used for can reaching an order of magnitude from the variation of the gain factor μ of the LMS of optimal self-adaptive DFF signal processing method, so adopts the stable RLS method of Fast numerical of determining the index weight factor to be difficult to adapt to the quick variation of underwater sound signal in the United States Patent (USP) 5844951.As shown in Figure 12, space diversity of the present invention, from the optimal self-adaptive DFF and from the optimal self-adaptive phase tracker at operating distance 2000m place, reach transmission rate 10kbits/s and bit error probability 1.90 * 10 ^-5

The results are shown in Figure 13 with identical test data analysis among the phase tracker of the adaptive decision feedback equalizer of the space diversity in the United States Patent (USP) 5844951, RLS method that Fast numerical is stable and second-order PLL pair and Figure 12.As seen from the figure, at operating distance 2000m place, reach transmission rate 10kbits/s and bit error probability 1.90 * 10 ^-2, obviously be inferior to result of the present invention.

Embodiment 2

Make a underwater sound coherent communication system that is used for high bit rate, the low level probability of error according to Fig. 1, Fig. 2 and Fig. 3, on another lake, test.Test lays figure with seeing Figure 17 on the lake.The structure of this system, arrangement and process of the test are identical with embodiment 1.

With space diversity of the present invention, from the optimal self-adaptive DFF with from optimal self-adaptive phase tracker Figure 18 that the results are shown in to experimental data processing.By Figure 18 (a) as seen, the gain factor γ that the present invention is used for the LMS estimator of phase tracker reaches several times three passage differences, and the variation of γ reaches an order of magnitude in the same passage.Therefore adopt second order digital phase-locked loop to be difficult to the quick variation of detection and tracking underwater sound signal phase place in the United States Patent (USP) 5844951 with two preset parameters.Can see by Figure 18 (b), the present invention is used for having variation fast from the gain factor μ of the LMS of optimal self-adaptive DFF signal processing method, so adopts the stable RLS method of Fast numerical of determining the index weight factor to be difficult to adapt to the quick variation of underwater sound signal in the United States Patent (USP) 5844951.As shown in Figure 18, space diversity of the present invention, from the optimal self-adaptive DFF and from the optimal self-adaptive phase tracker at operating distance 4000m place, reach transmission rate 10kbits/s and bit error probability 1.70 * 10 ^-5

The results are shown in Figure 19 with identical test data analysis among the phase tracker of the adaptive decision feedback equalizer of the space diversity in the United States Patent (USP) 5844951, RLS method that Fast numerical is stable and second-order PLL pair and Figure 18.As seen from the figure, at operating distance 4000m place, reach transmission rate 10kbits/s and bit error probability 2.15 * 10 ^-2Obviously be inferior to result of the present invention.

For the ease of understanding, the present invention is narrated with embodiment in conjunction with the accompanying drawings, be appreciated that the present invention has a lot of embodiment, but the invention is not restricted to these figure and embodiment.The present invention includes the present invention's spirit and the interior amendment of the interior all authority claimed range of scope.

Claims (1)

1. the method for processing signals of a high code speed and low error probability underwater sound coherent communication system is characterized in that: the processing procedure that comprises emission process, receiving course and the received signal of signal; Wherein the emission process of signal comprises: main frame/slave is at first modulated data to be sent, and the data after the modulation are delivered to transmitter through IOC, and transmitter drives transmitting transducer/transmitting-receiving and share transducer emission sound wave; Wherein the receiving course of main frame comprises: the slave emitting sound wave is at water transmission, each hydrophone of the reception linear array of main frame converts the acoustic signals that receives to the signal of telecommunication multipath receiver of feeding, and multipath receiver is handled after the multi-channel data acquisition device becomes digital signal; Wherein the receiving course of slave comprises: the main frame emitting sound wave is at water transmission, and the transmitting-receiving of slave is share transducer the acoustic signals that receives is converted to the signal of telecommunication receiver of feeding, and receiver is handled after data acquisition unit becomes digital signal; Wherein the processing procedure of received signal comprises: digitized received signal is handled in high speed digital signal processor, and the result of acquisition exists in the hard disk, perhaps delivers in other terminal equipment via serial port; The data-modulated mode of emission process is the multiple phase shift keying modulation; The receiving course of main frame adopts reception linear array, multipath receiver and the multi-channel data acquisition device with a plurality of hydrophones, implementation space diversity; Processing procedure adopts space diversity, multi-channel adaptive DFF and from optimal self-adaptive phase tracker united signal processing method, wherein the multi-channel adaptive DFF adopts quick self-optimizing least mean-square error method, and its gain factor μ adopts least mean-square error method self adaptation to adjust; From the optimal self-adaptive phase tracker signal of a plurality of passages is carried out phase compensation respectively, adopt quick self-optimizing least mean-square error method, its gain factor λ adopts least mean-square error method self adaptation to adjust.

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