CN204462385U - A kind of acoustics seabed Range Measurement System - Google Patents

Abstract

The utility model relates to an acoustic seabed distance measurement system, comprising: a transducer, a pressure-resistant housing, an electronic cabin, a watertight flange, a watertight connector, a receiving and transmitting module, a power supply management module, a duty circuit module, a working circuit module and peripherals module; the electronic cabin is installed in the pressure-resistant shell, and watertight flanges are installed at both ends of the opening; a transducer is connected to one watertight flange, and a watertight connector is connected to the other watertight flange; receiving and transmitting modules, power management modules , the duty circuit module, the working circuit module and the peripheral module are located in the electronic cabin; the transducer is used to convert the signal between the electrical signal and the acoustic signal; The power supply is managed; the on-duty circuit module is used to complete the duty task, cooperates with the power management module to complete the power management control task, and transmits the measured propagation distance of the acoustic signal between two points to the data recording device; the working circuit module is used to complete the real-time measurement away from the task.

Description

An Acoustic Seabed Distance Measuring System

technical field

The utility model relates to the field of seabed acoustic ranging, in particular to an acoustic seabed distance measuring system and method.

Background technique

The submarine acoustic ranging system uses acoustic ranging to measure the distance between multiple points on the seabed. As shown in Figure 1, the working principle of the submarine acoustic ranging system is: place a set of ranging systems on the submarine target points A and B respectively, and according to the set parameters, the ranging system at point A periodically transmits ranging acoustic pulse signals After receiving the ranging acoustic pulse signal, the point B ranging system replies with a response acoustic pulse signal, and the point A ranging system receives the response acoustic pulse signal of the point B ranging system, and calculates the transmission time of the acoustic signal between the two points Time τ, and then according to the known speed of sound c, the distance R between points A and B can be calculated.

With the development of marine resources, the construction of various marine projects, and the investigation and exploitation of offshore oil and gas and deep-sea mineral resources, the impact of human activities on the seabed environment and the artificial or natural geological activities on the seabed, changes in seabed topography, Both the measurement and monitoring of seafloor plate activity have raised new requirements. However, the existing underwater distance measurement system is limited by the bandwidth limitation and the complexity of the marine environment, and the distance measurement accuracy is not high.

Utility model content

The purpose of the utility model is to overcome the defect of the existing underwater acoustic distance measurement system that the distance measurement accuracy is not high, so as to provide a high-precision acoustic seabed distance measurement system and method.

In order to achieve the above purpose, the utility model provides an acoustic submarine distance measurement system, including: a transducer 1, a pressure-resistant housing 2, an electronic cabin 3, a watertight flange 4, a watertight connector 5, a receiving and transmitting module 6, Power management module 7, duty circuit module 8, working circuit module 9 and peripheral module 10; Wherein,

The pressure-resistant housing 2 is a cylindrical structure with openings at both ends, and an electronic cabin 3 is installed inside it. A watertight flange 4 is respectively installed at both ends of the opening of the pressure-resistant housing 2; one of the watertight flanges is connected to There is a transducer 1, and another watertight flange is connected with a watertight connector 5; the receiving and transmitting module 6, the power management module 7, the duty circuit module 8, the working circuit module 9 and the peripheral module 10 are all located in the electronic cabin 3 Inside; the transducer 1 is used to convert the signal to be received or transmitted between the electrical signal and the acoustic signal, and it is connected to the receiving and transmitting module 6 in the electronic cabin 3 through a cable; the receiving and transmitting module 6 is used for receiving and transmitting signals; the power management module 7 is used to manage the power of other components in the system; the on-duty circuit module 8 is used to complete duty tasks, cooperate with the power management module 7 to complete power management control tasks, and test The transmission distance of the acoustic signal obtained between two points is transmitted to an external data recording device; the working circuit module 9 is used to complete the real-time ranging task; the peripheral module 10 includes a pressure sensor 21 for measuring depth information and An attitude sensor 23 for measuring the attitude of the device.

In the above technical solution, the receiving and transmitting module 6 includes a transceiving switch 11, a receiver 12 and a transmitter 13; wherein, the function of the transceiving switch 11 is to use two high-speed diodes to protect the receiving stage in the receiving phase. The machine is free from the damage caused by the high voltage when transmitting, and prevents the receiving sensitivity of the system from being reduced in the transmitting stage; the function of the receiver 12 is to complete the filtering and amplification of the received signal, and the receiver 12 divides the filtered and amplified signal into Two ways, one way is sent to the duty circuit module 8, and the other way is sent to the working circuit module 9; the transmitter 13 is used to increase the power of transmission, realize the impedance matching between the power amplification stage and the transducer, and then improve the electroacoustic energy between conversion efficiencies.

In the above technical solution, the working circuit module 9 includes an analog-to-digital converter 15, a digital-to-analog converter 22, a watchdog 17, a signal processing unit 16, and an interface conversion 20; wherein the analog-to-digital converter 15 is used for collecting signal, the digital-to-analog converter 22 is used to output a signal, the watchdog 17 is used to perform a reset operation when the program accidentally runs away, and the signal processing unit 16 is used to detect the target signal, process the signal, Target signal parameter estimation and pulse selection, the interface conversion 20 is used to realize the communication between the working circuit module 9 and other modules.

In the above-mentioned technical scheme, described signal processing unit 16 adopts FPGA 18 and DSP 19 to realize; Wherein, FPGA 18 mainly completes the large amount of calculations including signal acquisition, preprocessing, narrowband filter and related operations, low computational complexity The DSP 19 is responsible for processing with a small amount of processing but high computational complexity, including judging and selecting pulses.

The utility model has the advantages of:

1. The utility model adopts high-precision time delay estimation to realize high-precision distance measurement on the seabed;

2. The utility model adopts a deep water pressure-resistant device, which provides a powerful guarantee for the normal operation of the submarine equipment.

Description of drawings

Fig. 1 is a schematic diagram of seabed acoustic ranging;

Fig. 2 is the overall structure schematic diagram of the acoustic submarine distance measurement system of the present utility model;

Fig. 3 is a functional module division diagram of the acoustic seabed distance measurement system of the present invention;

Fig. 4 is a schematic diagram of a working circuit module in the acoustic submarine distance measurement system of the present invention.

Detailed ways

Now in conjunction with accompanying drawing, the utility model is further described.

Referring to Fig. 2 and Fig. 3, the acoustic submarine distance measurement system of the present invention includes: transducer 1, pressure-resistant housing 2, electronic cabin 3, watertight flange 4, watertight connector 5, receiving and transmitting module 6, power management Module 7, on-duty circuit module 8, working circuit module 9 and peripheral module 10; wherein, the pressure-resistant housing 2 is a cylindrical structure with openings at both ends, and an electronic cabin 3 is installed inside it. A watertight flange 4 is installed at both ends of the opening of 2; a transducer 1 is connected to one of the watertight flanges, and a watertight connector 5 is connected to the other watertight flange; the receiving and transmitting module 6 and the power management module 7 , the duty circuit module 8, the working circuit module 9 and the peripheral module 10 are all located in the electronic cabin 3; The cable is connected to the receiving and transmitting module 6 in the electronic cabin 3; the receiving and transmitting module 6 is used to receive and transmit signals; the power management module 7 is used to manage the power of other components in the system; the duty circuit module 8 Used to complete duty tasks, cooperate with power management module 7 to complete power management control tasks, and transmit the transmission distance of the measured acoustic signal to an external data recording device between two points; the working circuit module 9 is used to complete real-time measurement distance task; the peripheral module 10 includes a pressure sensor 21 for measuring depth information and an attitude sensor 23 for measuring the attitude of the device.

Each module in the acoustic seabed distance measurement system of the present invention will be further described below.

With reference to Fig. 3, described receiving and transmitting module 6 comprises transceiving combined switch 11, receiver 12 and transmitter 13; Wherein, the effect of described transceiving combined switch 11 is to utilize two high-speed diodes to protect the receiver in the receiving stage Avoid the damage caused by the high voltage during transmission, and prevent the receiving sensitivity of the system from being reduced during the transmission phase; the function of the receiver 12 is to complete the filtering and amplification of the received signal, and the receiver 12 divides the filtered and amplified signal into two paths, One way is sent to duty circuit module 8, and one way is sent to working circuit module 9; Described transmitter 13 is used for improving the power of transmission, realizes the impedance matching between power amplification stage and transducer, and then improves the electroacoustic energy between conversion efficiency.

The power management module 7 is used to control the power of the working circuit module 9 , the transmitter 13 and the peripheral module 10 . The acoustic seabed distance measurement system of the present invention has two states, that is, a working mode and an on-duty mode. In the working mode, the power management module 7 provides normal power supply for other modules in the system. In the duty mode, the power management module 7 provides the other modules in the system with the low voltage that only maintains the minimum work requirement under the management of the duty circuit module 8. voltage, in order to save power consumption and ensure that the system works for a long time underwater.

The on-duty circuit module 8 is realized by MCU14. In one embodiment, the MCU used has the characteristics of low power consumption and high processing performance. The on-duty circuit module 8 ensures that when there is no real-time ranging task, the system enters the on-duty mode. This module manages the power management module 7 and the like under the on-duty mode to ensure the normal standby state of the system. After receiving the underwater acoustic remote control command, from The on-duty mode is switched to the working mode, and after the task is completed, it returns to the on-duty mode to wait for the next command.

With reference to Fig. 3 and Fig. 4, described working circuit module 9 comprises ADC (analog-to-digital converter) 15, DAC (digital-to-analog converter) 22, watchdog (Watch Dog) 17, signal processing unit 16 and interface conversion 20; Wherein, the ADC 15 is used to collect signals, the DAC 22 is used to output signals, the Watch Dog 17 is used to perform a reset operation when the program runs unexpectedly, and the signal processing unit 16 is used to detect target signals, Signal processing, target signal parameter estimation and pulse selection, the interface conversion 20 is used to realize the communication between the working circuit module 9 and other modules. As shown in Figure 4, described signal processing unit 16 has adopted FPGA 18 and DSP 19 when hardware is realized; , Calculations with low computational complexity, DSP 19 is responsible for judging and selecting pulses, etc., which have a small amount of processing but high computational complexity. Since the signal processing unit 16 uses FPGA to realize signal acquisition, that is, it adopts hardware means to realize time delay measurement, which has higher precision than software.

After the signal processing unit 16 in the working circuit module 9 receives the command to upload the depth information, it turns on the power control signal of the pressure sensor 21 in the peripheral module 10, and the pressure sensor 21 reads the depth information several times continuously, and averages the depth information Then upload it through the underwater acoustic communication mode.

The above is the structural description of the acoustic seabed distance measurement system of the present invention. When using this system to measure the acoustic seabed distance, at least two sets of equipment need to be coordinated to complete it. As shown in Figure 1, the first set of acoustic seabed distance measurement system is recorded The second set of acoustic submarine distance measurement system is denoted as ranging system B as ranging system A. The method of how to use the acoustic seabed distance measurement system of the present invention to realize the acoustic seabed distance measurement will be described in detail below.

The method includes the following steps:

Step 1), send communication:

The signal processing unit 16 of the ranging system B sends an inquiry signal in the form of an electric signal, and transmits it to the transmitter 13 after passing through the DAC 22; the transmitter 13 transmits the inquiry signal in the form of an electric signal to the transducer 1, and the transducer 1 sends the electric signal to the transducer 1. The interrogation signal in signal form is converted into an acoustic signal and then transmitted through the underwater acoustic communication channel;

Step 2), communication receiving: the transducer 1 of the ranging system A receives the inquiry signal in the form of an acoustic signal sent by the ranging system B through the underwater acoustic communication channel, and converts the signal into an electrical signal; The receiver 12 receives the inquiry signal in the form of an electrical signal, and transmits it to the signal processing unit 16 after the ADC 15;

The functions of the communication sending and receiving described in the above step 1) and step 2) are to realize the synchronization problem between the two systems.

Step 3), ranging sending: the signal processing unit 16 of the ranging system B sends an inquiry signal in the form of an electric signal, which is transmitted to the transmitter 13 after passing through the DAC 22, and the transmitter 13 transmits the inquiry signal in the form of an electric signal to the transducer 1. The transducer 1 of the ranging system B converts the interrogation signal in the form of an electrical signal into an acoustic signal and transmits it through the underwater acoustic communication channel;

Step 4), ranging receiving: the transducer 1 of the ranging system A receives the inquiry signal sent by the ranging system B through the underwater acoustic communication channel, and converts the signal into an electrical signal; the receiver 12 in the receiving transmitter module 6 The inquiry signal in the form of an electrical signal is received and transmitted to the signal processing unit 16 after passing through the ADC 15 . After the signal processing unit 16 receives the inquiry signal, it responds, and the response signal of the ranging system A is transmitted to the transmitter 13 after passing through the DAC 22, and the transmitter 13 transmits the response signal in the form of an electrical signal to the transducer 1, and the ranging system A The transducer 1 of A converts the response signal in the form of an electrical signal into an acoustic signal and transmits it through the underwater acoustic communication channel;

The transducer 1 of the ranging system B receives the response signal of the ranging system A, and the signal processing unit 16 of the ranging system B calculates the transmission distance of the acoustic signal between two points, and transmits the distance to an external data recording device .

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present utility model rather than limit them. Although the present utility model has been described in detail with reference to the embodiments, those skilled in the art should understand that any modification or equivalent replacement of the technical solution of the present utility model does not depart from the spirit and scope of the technical solution of the present utility model, and all of them should cover In the scope of the claims of the present utility model.

Claims (4)

1. An acoustic seafloor distance measurement system, comprising: the energy converter comprises an energy converter (1), a pressure-resistant shell (2), an electronic cabin (3), a watertight flange (4), a watertight connector (5), a receiving and transmitting module (6), a power management module (7), a duty circuit module (8), a working circuit module (9) and an external module (10); wherein,

the pressure-resistant shell (2) is of a cylindrical structure with openings at two ends, an electronic cabin (3) is installed in the pressure-resistant shell, and watertight flanges (4) are respectively installed at two ends of the opening of the pressure-resistant shell (2); one watertight flange is connected with an energy converter (1), and the other watertight flange is connected with a watertight connector (5); the receiving and transmitting module (6), the power management module (7), the duty circuit module (8), the working circuit module (9) and the peripheral module (10) are all positioned in the electronic cabin (3); the transducer (1) is used for converting an electric signal and an acoustic signal of a signal to be received or transmitted and is connected to a receiving and transmitting module (6) in the electronic cabin (3) through a cable; the receiving and transmitting module (6) is used for receiving and transmitting signals; the power supply management module (7) is used for managing the power supply of other components in the system; the on-duty circuit module (8) is used for completing an on-duty task, completing a power management control task by matching with the power management module (7), and transmitting the measured propagation distance of the acoustic signal between two points to external data recording equipment; the working circuit module (9) is used for completing a real-time distance measurement task; the peripheral module (10) comprises a pressure sensor (21) for measuring depth information and an attitude sensor (23) for measuring the attitude of the device.

2. An acoustic seafloor distance measuring system according to claim 1, wherein the receiving and transmitting module (6) comprises a transmit-receive switch (11), a receiver (12) and a transmitter (13); the receiving and transmitting combined switch (11) is used for protecting a receiver from being damaged by high voltage during transmission by using two high-speed diodes in a receiving stage and preventing the receiving sensitivity of the system from being reduced in a transmitting stage; the receiver (12) is used for filtering and amplifying received signals, the receiver (12) divides the filtered and amplified signals into two paths, one path is sent to the on-duty circuit module (8), and the other path is sent to the working circuit module (9); the transmitter (13) is used for improving the transmitting power, realizing the impedance matching between the power amplification stage and the energy converter and further improving the conversion efficiency between the electroacoustic energy.

3. An acoustic seafloor distance measurement system according to claim 1, wherein the operating circuit module (9) comprises an analogue to digital converter (15), a digital to analogue converter (22), a watchdog (17), a signal processing unit (16) and an interface conversion (20); the analog-digital converter (15) is used for collecting signals, the digital-analog converter (22) is used for outputting signals, the watchdog (17) is used for resetting when a program runs unexpectedly, the signal processing unit (16) is used for detecting target signals, processing the signals, estimating parameters of the target signals and selecting pulses, and the interface conversion (20) is used for realizing communication between the working circuit module (9) and other modules.

4. An acoustic seafloor distance measurement system according to claim 3, wherein the signal processing unit (16) is implemented using an FPGA (18) and a DSP (19); the FPGA (18) mainly completes large computation including signal acquisition, preprocessing, a narrow-band filter and related computation and low computation complexity, and the DSP (19) is responsible for processing with small processing amount including pulse judgment and selection and high computation complexity.