CN114885275B - High-precision wireless beacon device, system and communication method based on multimode communication - Google Patents

Abstract

The invention relates to the technical field of navigation communication positioning, and discloses a high-precision wireless beacon device, a system and a communication method based on multimode communication, wherein the device comprises an antenna array, a microwave network module, a power management module, a main controller, a first wireless communication module and a second wireless communication module, wherein the first wireless communication module and the second wireless communication module respectively comprise an LORA communication module, a cellular mobile network communication module, a Beidou RDSS module and a multimode positioning module; one end of the LORA communication module, the positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with the main controller, and the other end of the LORA communication module, the positioning module, the cellular mobile network communication module and the Beidou RDSS module are connected with the antenna array through the microwave network module. The invention can improve the reliability of the wireless beacon.

Description

High-precision wireless beacon device, system and communication method based on multimode communication

Technical Field

The invention relates to the technical field of navigation and communication positioning. In particular to an important target searching and positioning and information communication technology, in particular to a high-precision wireless beacon device, a system and a communication method based on multimode communication.

Background

At present, the industries of aviation, aerospace and the like pay more and more attention to the research and the recovery of important parts in the process of flying and moving products, the appearance and the equipment state of the parts can reflect the mechanical overload, vibration and thermal shock working conditions in the working process, and meanwhile, the real-time data stored by the parts are more related to the health monitoring record of carrier products, and are the most reliable, most scientific, most effective and most direct basis for the upgrade and optimization of carrier performance and the analysis of fault reasons, such as a 'black box' of an aircraft. The key to timely positioning and recycling of such products is whether the products have the functions of acquiring positioning information in real time and informing searching personnel in time, and the existing technical means mainly rely on technical personnel to calculate and start searching according to a preset target motion track, or utilize a GPS satellite positioning terminal and a GSM communication technology to accurately position and track a remote target in real time. The former consumes time, manpower, material resources, and is with high costs, and the search effect is poor, and the latter receives mobile operator's basic station arrangement restriction, has the potential safety hazard of location data simultaneously, so urgent need a security height, more reliable, more stable target location means comes to carry out the position acquisition to the target, develops a product that has the beacon function or the beacon device of the same motion trail that the product has, has important value to the search of flight motion class product or part. The beacon device has a power supply function with a lithium battery, can continue a journey for several hours or even dozens of hours according to the battery capacity, and generally, the positioning information of the beacon device is sent in a point-to-point encryption mode in order to protect the safety of a target position.

Disclosure of Invention

The invention overcomes the defects of the prior art, and solves the technical problems that: a high-precision wireless beacon device, a system and a communication method based on multimode communication are provided, and the reliability of the wireless beacon is improved.

In order to solve the technical problems, the invention adopts the technical scheme that: a high-precision wireless beacon device based on multi-mode communication comprises an antenna array, a microwave network module, a power management module, a main controller, a first wireless communication module and a second wireless communication module, wherein the first wireless communication module and the second wireless communication module have the same structure and respectively comprise an LORA communication module, a cellular mobile network communication module, a Beidou RDSS module and a multi-mode positioning module; one end of each of the LORA communication module, the multimode positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with a main controller, the other end of each of the LORA communication module, the multimode positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with the antenna array through the microwave network module, the microwave network module comprises a plurality of power division combiners, the antenna array comprises a plurality of antenna pairs, the LORA communication module, the multimode positioning module, the cellular mobile network communication module and the Beidou RDSS module are connected with one antenna pair through the power division combiners, and the main controller is used for fusing positioning information received by the multimode positioning module to form a new information frame and then sending the new information frame through the Beidou RDSS module, the cellular mobile network communication module and the LORA module in the corresponding wireless communication module.

The high-precision wireless beacon device based on multimode communication comprises two main controllers, wherein the two main controllers carry out interactive operation in a high-frequency time-sharing mode;

the multi-mode positioning module comprises a Beidou RNSS positioning module and a GPS/GLONASS positioning module.

The microwave network module comprises eight groups of power dividing combiners; the antenna array comprises a first antenna pair, a second antenna pair, a third antenna pair and a fourth antenna pair;

the Beidou RDSS module and the multimode positioning module in the first wireless communication module are respectively connected with the first antenna pair through a power splitting combiner; the Beidou RDSS module and the multimode positioning module in the second wireless communication module are respectively connected with the second antenna pair through a power splitting combiner;

the cellular mobile network communication module and the LORA communication module in the first wireless communication module are respectively connected with the third antenna pair through a power splitting combiner, and the cellular mobile network communication module and the LORA communication module in the second wireless communication module are respectively connected with the fourth antenna pair through a power splitting combiner.

The first wireless communication module and the second wireless communication module further comprise an RS422 interface module and an optical coupling interface module;

the RS422 interface module is connected with the main controller and is used for realizing data or instruction interaction;

and the optical coupling interface module is connected with the main controller and used for receiving a power supply monitoring signal of an external power supply system.

The antenna pair comprises two groups of antennas which are arranged in a back-to-back manner to form an omnidirectional combination.

The power management module comprises a charging management module, a lithium battery pack, a relay module, a double-path selection circuit and a wide-voltage input DCDC module, an external power supply charges the lithium battery pack through the charging management module, the output end of the lithium battery pack is connected with the DCDC module through the relay module and the double-path selection circuit, the external power supply is connected with the DCDC module through the double-path selection circuit, and the DCDC module is used for performing voltage conversion on the output of the external power supply or the output of the lithium battery pack and then supplying power to each module; and the control end of the relay module is connected with the main controller.

The relay module comprises two relay control circuits, the control ends of the two relay control circuits are connected with the output end of the main controller, one end of the relay module is connected with the output end of the lithium battery pack after the relay contacts in the two relay control circuits are connected in parallel, and the other end of the relay module is connected with the double-path selection circuit.

In addition, the invention also provides a high-precision wireless beacon system based on multimode communication, which comprises the high-precision wireless beacon device based on multimode communication and two searching system receiving ends, wherein the searching system receiving ends comprise a mobile receiving module and an LORA receiving module, the mobile receiving module is used for receiving the information sent by the cellular mobile network communication module, and the LORA receiving module is used for receiving the information sent by the LORA communication module.

In addition, the invention also provides a high-precision wireless beacon communication method based on multimode communication, which is realized by adopting the high-precision wireless beacon device based on multimode communication and comprises the following steps:

s1, initializing system parameters through a main controller;

s2, initializing a watchdog by the main controller, and establishing a positioning information acquisition path;

s3, after the communication modules are reset, judging whether the positioning information is successfully acquired, if so, storing the positioning data, and entering the step S4, and if not, returning to the step S2;

and S4, establishing a wireless transmission channel, and alternately transmitting data through the first wireless communication module and the second wireless communication module.

In step S1, initializing system parameters includes: communication parameter configuration of an LORA communication module, a cellular mobile network communication module and a Beidou RDSS module, external power supply monitoring configuration, lithium battery voltage acquisition parameter configuration and lithium battery control IO output parameter configuration;

and the steps S2 to S4 are alternately performed by the two main controllers.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention provides a high-precision wireless beacon device, a system and a communication method based on multimode communication, wherein the device comprises two groups of independent communication modules, and each 1 group of modules comprises a Beidou RNSS + GPS/GLONASS multimode positioning module, a Beidou RDSS module, a cellular mobile network communication module (4G, 5G and the like) and an LORA communication module, so that the multimode positioning and the communication functions of short message communication, cellular mobile communication, LORA short-distance communication and the like can be realized; the device also comprises a power management module for system power supply and distribution and a main controller for data interaction and processing. The MCU control panel is used as a main controller to perform data interaction with the Beidou RNSS + GPS/GLONASS multimode positioning module, the Beidou RDSS module, the cellular mobile network module and the LORA module, positioning information is sent to a corresponding receiving terminal through the Beidou RDSS module, the cellular mobile network module and the LORA module respectively through the multimode positioning, and the reliability of the wireless beacon is improved.

2. The invention also adopts the redundant backup of the double main controllers to control the work of each communication module, the external communication, the lithium battery control and the like, thereby further improving the reliability of the device.

3. In order to increase the chance of capturing satellite signals, the invention adopts two groups of antennas which are mutually redundant and point to different directions, thereby improving the signal capturing capability of the device.

4. Meanwhile, in order to ensure reliability, the wireless beacon device is also provided with a wired interface module which can perform data interaction with external equipment, so that functions of configuration information binding, remote control, data monitoring and the like are realized.

Drawings

Fig. 1 is a schematic structural diagram of a high-precision wireless beacon apparatus based on multimode communication according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a high-precision wireless beacon apparatus based on multimode communication according to a second embodiment of the present invention;

fig. 3 is a schematic structural diagram of a power management module according to a third embodiment of the present invention;

fig. 4 is a schematic circuit diagram of a relay module according to a third embodiment of the present invention;

fig. 5 is a schematic structural diagram of a high-precision wireless beacon system based on multimode communication according to a fourth embodiment of the present invention;

fig. 6 is a flowchart illustrating a high-precision wireless beacon communication method based on multimode communication according to a fifth embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

As shown in fig. 1, a first embodiment of the present invention provides a high-precision wireless beacon device based on multimode communication, including an antenna array, a microwave network module, a power management module, a main controller, a first wireless communication module and a second wireless communication module, where the first wireless communication module and the second wireless communication module have the same structure and both include an LORA communication module, a multimode positioning module, a cellular mobile network communication module and a beidou RDSS module; one end of each of the LORA communication module, the positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with a main controller, the other end of each of the LORA communication module, the positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with the antenna array through the microwave network module, the microwave network module 8 groups of power splitting and combining devices are arranged on the antenna array, the LORA communication module, the cellular mobile network communication module, the multimode positioning module and the Beidou RDSS module are all connected with one antenna pair through the microwave network module, and the main controller is used for fusing the multimode positioning module in each wireless communication module, the received positioning information and the equipment state information to form a new information frame and then sending the new information frame through the Beidou RDSS module, the cellular mobile network communication module and the LORA communication module in the corresponding wireless communication module.

Specifically, in this embodiment, the first wireless communication module and the second wireless communication module further include an RS422 interface module and an optical coupling interface module; the RS422 interface module is connected with the main controller and is used for realizing data or instruction interaction; and the optical coupling interface module is connected with the main controller and used for receiving a power supply monitoring signal of an external power supply system.

In addition, in this implementation, the multimode positioning module can position the beacon device through big dipper RNSS, GPS or GLONASS multimode, and big dipper RDSS module refers to big dipper RDSS short message communication module, and the system sends to main control unit after obtaining positioning information through the positioning module, and main control unit fuses the positioning information with equipment state information, forms new information frame, sends out according to predetermined destination address through big dipper RDSS short message communication module, cellular mobile network communication module and the LORA module among two wireless communication modules. In this embodiment, the minimum sending period of each RDSS short message module is 30 seconds, and in order to ensure that the sending interval of each short message is greater than 30 seconds, under the coordination of the main controller, each module increases the time by 10 seconds, so that the average sending of a message every 20 seconds can be realized, and the frequency and success rate of sending a short message before the equipment is damaged by falling to the ground can be increased. Therefore, for each short message module, the interval time is about 40 seconds and is greater than the limit of the Beidou card for 30 seconds, and the use requirement is met. If a 60 second card is used, the average speed can be increased to 35 seconds/time by switching time division multiplexing by two cards. If the communication card can be applied to a level-1-second RDSS communication card of the Beidou higher level, the communication speed can be higher.

In this embodiment, LORA communication module, cellular mobile network communication module big dipper RNSS + GPS/GLONASS multimode orientation module cellular mobile network communication module and big dipper RDSS module all adopt ripe technical function module for product inner structure is clear, and the functional partitioning is clear and definite, and the debugging is convenient. In addition, the device includes two sets of big dipper short message modules, has increased redundancy, and every module transmission interval X second (X is the communication restriction time of current big dipper card), two short message modules can reduce the transmission interval to being less than X/2 second +5 seconds, if adopt 30 seconds communication card, big dipper RDSS communication frequency can reach 20 seconds. The cellular mobile network communication module may be a mobile/universal 3G, 4G or 5G communication module.

In this embodiment, the dual cellular mobile network communication module and the LORA communication module are used to increase redundancy, and assuming that each module has a transmission interval of Y seconds, the dual cellular mobile network communication module may reduce the transmission interval to less than Y/2 seconds.

In addition, in this embodiment, a watchdog is added in the main control program of the main controller, and no watchdog is fed for more than 4 seconds, and the program is reset and runs from the beginning. Program run-off under abnormal conditions is avoided. Important information in the main control program is monitored in real time through the RS422 interface module and the monitoring equipment, so that faults can be found in advance, and the faults of the equipment can be diagnosed and analyzed in the later period.

In this embodiment, the LORA communication module is a wireless serial module with small size, low power consumption, high performance and long distance. The module design is to adopt an efficient ISM frequency band radio frequency spread spectrum chip, the module adopts the working frequency of 470Mhz to 510Mhz recommended by the China LoRa application alliance, parameters can be modified online through AT instructions, and LORA communication is transmitted by fixed channel broadcasting. The LORA has the advantage of long-distance anti-interference. Under an open ideal environment, the communication distance can reach up to 5km, fixed-point transmission, broadcast transmission and channel monitoring are supported, air awakening (ultra-low power consumption) is supported, FE forward error correction is supported, and the communication stability is improved. LORA uses broadcast fixed-point communication to prevent packet collision, similar to cellular mobile network communication modules.

In addition, in this embodiment, a binding function is further configured: in order to guarantee upgradable maintenance of products, a system communication setting interface is reserved in the wireless beacon device, the wireless beacon device can be communicated with a computer through an RS422 interface, a main controller is independently configured, communication time of each wireless communication module and communication intervals are included, beidou and cellular network receiving terminal card number configuration and LORA receiving terminal address and channel configuration are included, and meanwhile, the relay can be controlled to be powered off.

In addition, the beacon device is also provided with a data monitoring function: in order to store the positioning data of the wireless beacon device, the system can store the data in real time through a wire, and can output the data to a computer or other monitoring terminals through an RS422 interface module for visual display. Visual data analysis software of the monitoring terminal has the function of analyzing positioning information and equipment state information in real time, and simultaneously, target searching navigation is carried out according to the analysis position synchronous navigation map.

Example two

As shown in fig. 2, a second embodiment of the present invention provides a high-precision wireless beacon device based on multimode communication, which includes an antenna array, a microwave network module, a power management module, a first wireless communication module and a second wireless communication module, where the first wireless communication module and the second wireless communication module have the same structure, and unlike the first embodiment, the wireless beacon device in this embodiment includes two main controllers, and the two main controllers perform an interactive operation in a high-frequency time-sharing mode.

In addition, in this embodiment, the microwave network module includes 8 groups of power splitters; the antenna array comprises four antenna pairs, wherein a first antenna pair comprises antennas A1 and A2, a second antenna pair comprises antennas B1 and B2, a third antenna pair comprises antennas C1 and C2, and a fourth antenna pair comprises antennas D1 and D2; the Beidou RDSS module and the multimode positioning module in the first wireless communication module are respectively connected with the first antenna pair through a power dividing combiner; a cellular mobile network communication module and an LORA communication module in the first wireless communication module are respectively connected with a third antenna pair C1 and C2 through a power division combiner, and a Beidou RDSS module in the second wireless communication module is connected with a second antenna pair through a power division combiner; the Beidou RDSS module and the multimode positioning module in the second wireless communication module are respectively connected with the second antenna pair through a power splitting combiner; the cellular mobile network communication module and the LORA communication module in the second wireless communication module of the cellular mobile network communication module are connected to the fourth antenna pair through a power splitting/combining device. A third antenna pair and a fourth antenna pair, each antenna integrating a LORA antenna and a 4GLTE or 5G antenna. Through the arrangement, the first wireless communication module corresponds to two groups of antenna pairs (A1, A2 and C1, C2), the second wireless communication module corresponds to two groups of antenna pairs (B1, B2 and D1, D2), and each wireless communication module has the antenna pair of the wireless communication module, so that the safety of the system is further improved.

Further, in this embodiment, the antenna pair includes two sets of antennas, and the two sets of antennas are installed in opposite directions to form an omnidirectional combination. According to the embodiment, the eight-antenna redundancy design can ensure that the navigation satellite signals can be obtained to the greatest extent under any posture, and the communication reliability is improved.

In the embodiment, the low-power-consumption single chip microcomputer is used as the main controller, the product integration level is improved, meanwhile, a high-frequency time-sharing multiplexing mode is adopted, the two CPUs are in interactive operation, in order to ensure that the instantaneous load power is not too large, the two CPUs are in time-sharing wireless module control communication, the power consumption and the size are reduced, and the reliability and the safety are improved.

Further, in this embodiment, in order to realize the antenna miniaturization design of the wireless beacon device, the LORA antenna selects a ceramic printed board with a high dielectric constant, and the 4GLTE antenna or the 5G antenna adopts a PIFA antenna form, and realizes the multi-frequency technology by a slot method.

In this embodiment, the wireless beacon device includes 1 group of wired communication (RS 422 interface module or other wired communication module) with the searched target, 4 groups of wireless communication modules (big dipper RDSS module, multimode positioning module, cellular mobile network communication module, LORA module), each module works independently, except that data information interaction needs to be performed through the main controller, and the basic positioning information sending function of the wireless beacon device is not affected by any module fault. And meanwhile, a dual-communication module is adopted for carrying out redundant positioning information sending design.

In this embodiment, 4 groups of 8 antennas are used to implement external communication of the wireless beacon device. And time-sharing communication is adopted, so that the phenomenon that the transmission power consumption is overlarge at the same time is avoided, and the continuous power supply working time of the lithium battery is shortened. The wireless beacon device belongs to wireless receiving and transmitting equipment, and is communicated with a searching system through a navigation satellite, a base station and the like, all modules are in independent communication, and the searching system has no frequency requirement on receiving and can receive at any time. The searching system realizes unique position identification of different wireless beacon devices according to SIM information installed on the wireless beacon devices, and realizes once 30s communication according to the communication mode of the Beidou card, and the wireless beacon devices are internally provided with double backup modules, so that target positioning can be realized as long as 1 packet of data is received. Therefore, the wireless beacon devices at different positions can work independently without cooperation and can communicate with the remote search system independently.

In this embodiment, since the wireless beacon device has two independent positioning modules, the wireless beacon device can independently acquire the position information and combine the position information into a transmission data packet. As shown in fig. 2, in the layout, the antennas A1 and A2 are installed in opposite directions, and may form an omni-directional combined antenna pair; the B1 and B2 antennas are arranged in a reverse way, and can also form an omnidirectional combined antenna pair. The two antenna pairs do not transmit simultaneously, so no frequency interference is caused. In the same way, the cellular mobile network communication module and the LORA module adopt the antenna pair, wherein C1 and C2 are arranged in a back-to-back manner, and D1 and D2 are arranged in a back-to-back manner.

EXAMPLE III

The third embodiment of the invention provides a high-precision wireless beacon device based on multimode communication, which comprises an antenna array, a microwave network module, a power management module, a first wireless communication module and a second wireless communication module, wherein the first wireless communication module and the second wireless communication module have the same structure, as shown in fig. 3, the first wireless communication module and the second wireless communication module are different from the first embodiment in that in the first embodiment, the power management module comprises a charging management module, a lithium battery pack, a relay module P1, a two-way selection circuit U6 and a DCDC module, an external power supply is connected with the charging management module through a protection diode U5 to charge the lithium battery pack, the output end of the lithium battery pack is connected with the DCDC module through the relay module P1 and the two-way selection circuit U6, the external power supply is connected with the DCDC module through the two-way selection circuit U6, and the DCDC module is used for performing voltage switching on the output of the external power supply or the output of the battery pack and then performing secondary conversion on the voltage switching on the output of the lithium battery pack to supply power supply to each module; and the control end of the relay module is connected with the main controller. The DCDC module comprises a DC conversion chip U4 and a secondary power supply conversion module U8, wherein the DC conversion chip converts an external power supply into 12V direct-current voltage, and the secondary power supply conversion module U8 converts the 12V direct-current voltage into 3.3V and 5V direct-current voltages and then supplies power to the circuit.

Further, as shown in fig. 4, the relay module includes two relay control circuits, the control ends of the two relay control circuits are connected with the output ends of the main controller, namely, the control end of the main controller, is connected with the output end of the lithium battery pack, and after the relay contacts in the two relay control circuits are connected in parallel, one end of the relay contacts is connected with the output end of the lithium battery pack, and the other end of the relay contacts is connected with the two-way selection circuit. In fig. 4, the relay corresponding to the different levels of the control signals of the actr 1 and the actr 2 are respectively used to conduct and output the lithium battery. And the beacon device is prevented from being powered off due to the accidental reset of the system. When the relay is closed, the lithium battery can be guaranteed to supply power to the system by using Lictr1=1 or Lictr2=0, and when the relay is disconnected, the lithium battery can be guaranteed to supply power to the system by using Lictr1=0 and Lictr2= 1.

In this embodiment, power management module switches control group battery power supply through two relays, prevents to lead to unexpected outage because MCU resets, has functions such as EMI anti-electromagnetic interference and DCDC secondary power supply transform simultaneously. The description will be given by taking an external power supply input as an example: the external power supply is introduced through an interface and then divided into 3 paths, wherein 1 path charges the lithium battery through a protection diode U5, 1 path enters a DCDC conversion chip U3 through a branch of a double-path selection diode U6 to output DC12V, and in addition, 1 path enters an optical coupler P2 to acquire power supply state monitoring to inform the MCU whether the external power supply supplies power or not.

The lithium battery carries out charge management through the module of charging, get into relay module P1's input simultaneously, relay module is exported by MCU control signal control, when relay module switch-on, lithium battery voltage is given DC conversion chip U4 power supply through the other one end of double-circuit selection diode U6, DC conversion chip U4 gives secondary power supply transform module U8 and each communication module power supply after converting voltage into 12V direct current, secondary power supply transform module U8 gives main control unit and other module power supplies after with voltage conversion. Multiple power supply conversion prevents the risk of the whole function of the equipment from being lost due to the damage of a certain functional circuit.

In addition, as shown in fig. 3, in this embodiment, the main controller receives a power-off instruction of the lithium battery output from the outside through the RS422 interface P3, and the MCU interprets the instruction, thereby implementing power-off control of the wireless beacon device. The main controller transmits the real-time positioning information of the wireless beacon device and the working condition of the wireless beacon device to the data monitoring equipment in real time through an RS422 interface P4.

The wireless beacon device of the embodiment can perform wide-voltage power supply operation through the external nodes 9V to 36V. In addition, the device is provided with a lithium battery, can be charged through an external power supply port, and is converted into a lithium battery for power supply when the external power supply is disconnected, and the equipment continues to work until the equipment falls to the ground or the battery is exhausted. In order to protect the lithium battery from long-term multi-frequency overdischarge in a test state, the device is externally connected with a power-off instruction signal of the lithium battery, and the lithium battery can be actively controlled to be disconnected with other circuits in the device through the power-off instruction signal.

Example four

The fourth embodiment of the invention provides a high-precision wireless beacon system based on multimode communication, which comprises the high-precision wireless beacon device based on multimode communication in the first embodiment, the second embodiment or the third embodiment, and two groups of search system receiving ends, wherein the search system receiving ends comprise a mobile receiving module, an LORA receiving module and a short message receiving module, the mobile receiving module is used for receiving information sent by a cellular mobile network communication module, the LORA receiving module is used for receiving information sent by the LORA communication module, and the short message receiving module is used for receiving short message information sent by the Beidou RDSS module. And the receiving ends of the two groups of searching systems can complete function self-checking through mutual communication, so that reliable communication with the beacon device is ensured.

In this embodiment, the cellular mobile network communication module adopts an LTE cat.4 module with a four-module core, and can implement functions such as short message, network communication, base station positioning, FTP, HTTP, and the like. The module carries out positioning information interaction by adopting a network flow encryption communication mode. When the network is poor, the antenna pair connected with the cellular mobile network communication module adopts maximum power transmission. In order to ensure the normal work of the cellular mobile network communication module, the receiving end of the searching system samples the double cards to receive the positioning information. And sending communication information to a receiving module of the searching system in a cross way every 5 s. As shown in fig. 5, the beacon device transmits at an interval 1s between A1 and A2, after 5s, A3 and A4 transmit at an interval 1s, and 5s returns to A1 and A2 for transmission, and the whole period is 12s, the communication is performed for 4 times, and the communication frequency is 0.3Hz. Not only ensures the communication frequency, but also saves the power consumption.

Similarly, in order to reduce the probability of data loss when each link fails, the Beidou RDSS short message communication modules A and B and the receiving ends 1 and 2 of the searching system adopt an interactive sending mode, namely four data links A-1, B-1, A-2 and B-2, wherein the frequency of sending by the RDSS short message communication modules A and B is Xs +5s, but the sending interval of the RDSS short message communication modules A and B is set to be about X/2+5s, and the process is repeated. In this mode, even if any one Beidou RDSS module or the receiving end of the searching system fails, data can be ensured to be sent back. In the aspect of transmitting power, the A module and the B module are both 10W transmitting power, even though the power divider is used, the power distribution of the four antennas can also reach more than 4W, and the nominal power requirement of effective communication of Beidou RDSS is met.

The high-precision wireless beacon system of the embodiment adopts two sets of receiving end devices of the searching system to alternately receive the data sent by the two wireless communication modules, so as to form four communication links which are backup with each other, thereby increasing the reliability of the transmission link.

When the wireless beacon device operates, the wireless beacon device needs to be matched with a searching system Beidou RDSS short message communication, a cellular mobile network receiving terminal and an LORA receiving terminal machine carry out positioning data receiving, the wireless beacon device is provided with a Beidou antenna and is installed on a carrier, along with target motion, the position information of change after each positioning is sent to a Beidou satellite through a Beidou module and is forwarded to the searching system through the Beidou satellite, and on the other hand, the state monitoring data of the wireless beacon device is transmitted through an RS422 bus. In order to avoid single point failure as much as possible, the searching system can be provided with two receiving ends, and the two receiving ends upload the data to a computer through a serial port after receiving the data, store, display and analyze the data.

EXAMPLE five

As shown in fig. 6, a fifth embodiment of the present invention provides a high-precision wireless beacon communication method based on multimode communication, which is implemented by using the high-precision wireless beacon apparatus based on multimode communication, and includes the following steps:

s1, initializing system parameters through a main controller; in step S1, initializing system parameters includes: the system comprises a LORA communication module, a cellular mobile network communication module and a Beidou RDSS module, and also comprises external power supply monitoring configuration, lithium battery voltage acquisition parameter configuration and lithium battery control IO output parameter configuration.

S2, the main controller initializes the watchdog and establishes a positioning information acquisition path.

And S3, after the communication modules are reset, judging whether the positioning information is successfully acquired, if so, storing the positioning data, and entering the step S4, and if not, returning to the step S2.

And S4, establishing a wireless transmission channel, and alternately transmitting data through the first wireless communication module and the second wireless communication module.

Specifically, in this embodiment, steps S2 to S4 are performed alternately by two main controllers, and handshaking between the two main controllers ensures time synchronization of the controllers, and in addition, the two main controllers respectively control one wireless communication module to perform data transmission.

In this embodiment, the external system is powered on to supply power to the wireless beacon device, and the wireless beacon device automatically enters a normal operating state. The Beidou RNSS + GPS/GLONASS multimode positioning module starts satellite searching work, the main controller starts to communicate with the multimode positioning module and obtains response information (if the response information cannot be obtained, whether the following operation is continued or not is waited), and a sending frame is constructed by analyzing the received data. And meanwhile, collecting the voltage information of the lithium battery, encoding the voltage information into a sending frame, interacting the main controller with an LORA communication module and a cellular mobile network communication module to confirm the working state, trying to establish data communication with a nearby terminal, and sending the positioning information to a specified terminal. Under the external power supply state, the lithium cell is in charged state, and lithium cell power supply switch is closed simultaneously to prevent that wireless beacon device external power source from breaking off suddenly at any time, resulting in wireless beacon device unexpected outage.

When the external power supply stops, the wireless beacon device detects the state change, the wireless beacon device automatically switches to the lithium battery power supply, and the A and B modules are respectively controlled to alternately send information to the receiving ends 1 and 2 of the searching system according to the set sending sequence. Even if the multi-mode positioning module does not acquire effective real-time position information, the Beidou RDSS module periodically sends the finally received and cached information to a receiving end of a searching system, and the information is distinguished through time codes in the positioning information. Other partial circuits of the wireless beacon device maintain the previous working state unchanged, and can continuously work for at least more than 3h until a system is damaged or a battery is exhausted, or a power-off command of a lithium battery is received to perform power-off operation.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and these modifications or substitutions do not depart from the spirit of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A high-precision wireless beacon device based on multi-mode communication is characterized by comprising an antenna array, a microwave network module, a power management module, a main controller, a first wireless communication module and a second wireless communication module, wherein the first wireless communication module and the second wireless communication module have the same structure and respectively comprise an LORA communication module, a cellular mobile network communication module, a Beidou RDSS module and a multi-mode positioning module; one end of each of the LORA communication module, the multimode positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with a main controller, the other end of each of the LORA communication module, the multimode positioning module, the cellular mobile network communication module and the Beidou RDSS module is connected with the antenna array through the microwave network module, the microwave network module comprises a plurality of power division combiners, the antenna array comprises a plurality of antenna pairs, the LORA communication module and the cellular mobile network communication module are connected with one of the antenna pairs through the power division combiners, the multimode positioning module and the Beidou RDSS module are connected with the other antenna pair through the power division combiners, the main controller is used for fusing positioning information received by the multimode positioning module to form a new information frame, the new information frame is sent out through the Beidou RDSS module, the cellular mobile network communication module and the LORA module in the corresponding wireless communication module, and the power management module is used for supplying power to devices.

2. The high-precision wireless beacon device based on multimode communication is characterized by comprising two main controllers, wherein the two main controllers perform interactive operation in a high-frequency time-sharing mode;

the multi-mode positioning module comprises a Beidou RNSS positioning module and a GPS/GLONASS positioning module.

3. The high-precision wireless beacon device based on multimode communication of claim 1, wherein the microwave network module comprises eight groups of power splitting and combining devices; the antenna array comprises a first antenna pair, a second antenna pair, a third antenna pair and a fourth antenna pair;

the Beidou RDSS module and the multimode positioning module in the first wireless communication module are respectively connected with the first antenna pair through a power splitting combiner; the Beidou RDSS module and the multimode positioning module in the second wireless communication module are respectively connected with the second antenna pair through a power splitting combiner;

the cellular mobile network communication module and the LORA communication module in the first wireless communication module are respectively connected with the third antenna pair through a power splitting combiner, and the cellular mobile network communication module and the LORA communication module in the second wireless communication module are respectively connected with the fourth antenna pair through a power splitting combiner.

4. A high-precision wireless beacon device based on multi-mode communication according to claim 1, wherein the first wireless communication module and the second wireless communication module further comprise an RS422 interface module and an optical coupling interface module;

the RS422 interface module is connected with the main controller and is used for realizing data or instruction interaction;

and the optical coupling interface module is connected with the main controller and used for receiving a power supply monitoring signal of an external power supply system.

5. A high accuracy wireless beacon device based on multi-mode communication according to claim 1, wherein the antenna pair comprises two sets of antennas, the two sets of antennas are mounted opposite each other to form an omni-directional combination.

6. The high-precision wireless beacon device based on multimode communication of claim 1, wherein the power management module comprises a charge management module, a lithium battery pack, a relay module, a two-way selection circuit and a wide-voltage input DCDC module, an external power supply charges the lithium battery pack through the charge management module, an output end of the lithium battery pack is connected with the DCDC module through the relay module and the two-way selection circuit, the external power supply is connected with the DCDC module through the two-way selection circuit, and the DCDC module is used for performing voltage conversion on an output of the external power supply or an output of the lithium battery pack and then supplying power to each module; and the control end of the relay module is connected with the main controller.

7. The high-precision wireless beacon device based on multimode communication according to claim 6, wherein the relay module comprises two relay control circuits, control ends of the two relay control circuits are connected with an output end of the main controller, after relay contacts in the two relay control circuits are connected in parallel, one end of the relay control circuit is connected with an output end of the lithium battery pack, and the other end of the relay control circuit is connected with the two-way selection circuit.

8. A high-precision wireless beacon system based on multimode communication is characterized by comprising the high-precision wireless beacon device based on multimode communication of claim 1 and further comprising two groups of searching system receiving ends, wherein the searching system receiving ends comprise a mobile receiving module, an LORA receiving module and a short message receiving module, the mobile receiving module is used for receiving information sent by a cellular mobile network communication module, the LORA receiving module is used for receiving information sent by the LORA communication module, and the short message receiving module is used for receiving short message information sent by the Beidou RDSS module.

9. A high-precision wireless beacon communication method based on multimode communication, which is implemented by the high-precision wireless beacon device based on multimode communication of claim 2, and comprises the following steps:

s1, initializing system parameters through a main controller;

s2, initializing a watchdog by the main controller, wherein the watchdog is used for resetting a program and establishing a positioning information acquisition path;

s3, after the communication modules are reset, judging whether the positioning information is successfully acquired, if so, storing the positioning data, and entering the step S4, and if not, returning to the step S2;

and S4, establishing a wireless transmission channel, and alternately transmitting data through the first wireless communication module and the second wireless communication module.

10. The method according to claim 9, wherein the initializing system parameters in step S1 includes: communication parameter configuration of an LORA communication module, a cellular mobile network communication module and a Beidou RDSS module, external power supply monitoring configuration, lithium battery voltage acquisition parameter configuration and lithium battery control IO output parameter configuration;

and the steps S2 to S4 are alternately performed by the two main controllers.

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