CN107017908B - High-concurrency Internet of things big data communication method based on intelligent wearable equipment - Google Patents

Abstract

The invention relates to the technical field of communication, in particular to a high-concurrency Internet of things big data communication method based on intelligent wearable equipment, which adopts the following technical scheme: the system comprises an activation communication protocol, a positioning communication protocol, a setting communication protocol, a function communication protocol, a system communication protocol and an alarm instruction communication protocol; the six types of communication protocols do not influence each other and conflict with each other, and are stored in a storable medium; the communication standard of unified specification is established to the big data communication problem of high concurrency thing networking of intelligence wearing equipment, avoids constructing middleware cost, avoids purchasing third party service cost, avoids the problem that communication compatibility can not be guaranteed between the intelligence wearing equipment under the big data communication of high concurrency thing networking.

Description

High-concurrency Internet of things big data communication method based on intelligent wearable equipment

[ technical field ] A method for producing a semiconductor device

The invention relates to the technical field of communication, in particular to a high concurrency Internet of things big data communication method based on intelligent wearable equipment.

[ background of the invention ]

With the social progress, the internet technology is rapidly developed. Internet technology has affected people's lives and works. Along with the rapid development of intelligent wearing equipment and networks and the popularization of the concept of the internet of things, people have an increasing demand for realizing the big data communication between the intelligent wearing equipment and the internet of things. The applicant consults a lot of data, and at the present stage, the communication between the intelligent wearable devices of the internet of things has no standard or open specification. Communication among different equipment types needs to establish middleware or apply for obtaining third-party service, so that the cost is high, and later-period compatibility cannot be guaranteed. Therefore, a unified communication standard needs to be established, communication of the intelligent wearable device is standardized from the source, and interoperability is enhanced.

[ summary of the invention ]

The invention aims to provide a high-concurrency Internet of things big data communication method based on intelligent wearable equipment, which can standardize a service protocol of the intelligent wearable equipment in the Internet of things under high-concurrency Internet of things big data communication, enhance the safety and interoperability of communication, and solve the problems that the high-concurrency Internet of things big data communication of the intelligent wearable equipment is high in cost and cannot be guaranteed in later-period compatibility.

The invention discloses a high-concurrency Internet of things big data communication method based on intelligent wearable equipment, which adopts the following technical scheme:

the system comprises an activation communication protocol, a positioning communication protocol, a setting communication protocol, a function communication protocol, a system communication protocol and an alarm instruction communication protocol; the six types of communication protocols do not influence each other and conflict with each other, and are stored in a storable medium;

activation-type communication protocol: when the equipment changes the SIM card every time, the equipment needs to be activated to normally work, and the equipment activation instruction flow activities are as follows:

the method comprises the following steps: comprising a memory and a first communication link;

step two: at least one memory to implement a first communication link, the first communication link being an active type communication link;

step three: the device sends a 0001 activation instruction, and the server receives the 0001 instruction and judges the 0001 instruction;

step four: the server judges whether the instruction is correct, if the instruction is correct, a 0001 confirmation instruction is sent back to the equipment, and the equipment successfully receives the SIM activation;

step five: the server judges whether the instruction is correct, if the instruction is incorrect, when the 0001 instruction times exceed the limited times, the activation is failed, and if the result is correct, the activation is carried out at this time;

positioning type communication protocol: the method consists of an active positioning protocol and a passive positioning protocol, and the flow activities of the equipment positioning instruction are as follows:

the method comprises the following steps: comprising a memory and a second communication link;

step two: at least one memory to implement a second communication link, the second communication link being a positioning-type communication link;

step three: sending 0016 a real-time positioning starting instruction, sending 0017 a real-time positioning closing instruction or sending 0018 a primary positioning starting instruction to the equipment;

step four: the equipment responds to whether the instruction in the third step is received, and if the instruction is received, the equipment sends position data;

step five: when three instructions are sent out in the third step, the time interval between the instruction 0016 and the instruction 0017 is judged by the timer; if the GPS satellite data is confirmed, acquiring GPS satellite data, judging whether the GPS data changes between the two instructions, if not, ending, and failing to position; if so, uploading GPS data, and successfully positioning;

setting a communication protocol: the method supports the settings of equipment information uploading, heartbeat interval time, working modes and equipment monitoring time periods, and the setting type instruction flow activities are as follows:

the method comprises the following steps: comprising a memory and a third communication link;

step two: at least one memory to implement a third communication link, the third communication link being a setup-like communication link;

step three: sending an 0006 heartbeat instruction, an 0007 terminal working mode setting instruction, an 0009 monitoring time period device instruction, a 0011 terminal password setting instruction, a 0014 server IP setting instruction and a 0015 APN setting instruction to the device;

step four: setting whether to respond to the instruction in the third step; if so, the equipment receives the instruction in the step three and then sends a confirmation instruction of the instruction;

function type communication protocol: the process activities are as follows:

the method comprises the following steps: comprises a memory and a fourth communication link;

step two: at least one memory to implement a fourth communication link, the fourth communication link being a functional class communication link;

step three: sending a time control instruction, a 0023 check code instruction or a 0020GPRS line normal monitoring instruction;

step four: the equipment responds to the instruction in the third step, and whether the awakening time is up, whether a check code instruction is received or whether a GPRS circuit normal monitoring instruction is received; if the normal monitoring instruction of the GPRS circuit is not received for more than three times, the GPRS is restarted;

step five: in the fourth step, if the instruction in the third step is received, the device is awakened, the check code is displayed, and the position data, the 0023 confirmation instruction or the 0020 confirmation instruction are sent;

system-class communication protocol: and performing corresponding operations on equipment shutdown, factory reset and a dormant period, wherein the system class instruction flow activities are as follows:

the method comprises the following steps: comprises a memory and a fifth communication link;

step two: at least one memory to implement a fifth communication link, the fifth communication link being a system-class communication link;

step three: sending a 0021 remote shutdown instruction, a 0100 factory reset instruction or a 0099 hibernation instruction;

step four: if the equipment responds, the 0021 instruction, the 0100 instruction or the 0099 instruction is confirmed, and shutdown, factory equipment recovery or dormancy is executed;

alarm command communication protocol: the battery electric quantity is too low, and when equipment power state is unusual, can't support its normal work, will send battery voltage alarm information too low, alarm instruction flow activity is as follows:

the method comprises the following steps: comprises a memory and a sixth communication link;

step two: at least one memory to implement a sixth communication link, the sixth communication link being an alert instruction communication link;

step three: detecting the electric quantity, and sending a low-voltage alarm when the voltage of the battery is too low; and if the battery voltage is normal, ending the detection.

The invention has the beneficial effects that: according to the high-concurrency Internet of things big data communication method based on the intelligent wearable device, a unified and standardized communication standard is established for the problem of high-concurrency Internet of things big data communication of the intelligent wearable device, the cost of constructing middleware is eliminated, the cost of purchasing third-party service is eliminated, and the problem that the communication compatibility between the intelligent wearable devices cannot be guaranteed under the high-concurrency Internet of things big data communication is solved.

[ description of the drawings ]

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, and are not to be considered limiting of the invention, in which:

FIG. 1 is a flow diagram of a device activation communication process of one embodiment of the present invention;

FIG. 2 is a flow diagram of a device location communication process of one embodiment of the present invention;

FIG. 3 is a flow diagram of a device setup communication process of one embodiment of the present invention;

FIG. 4 is a flow diagram of a device function communication process of one embodiment of the present invention;

FIG. 5 is a flow diagram of a device system communication process of one embodiment of the present invention;

fig. 6 is a flow diagram of a device alert communication process according to one embodiment of the invention.

[ detailed description ] embodiments

The present invention will now be described in detail with reference to the drawings and specific embodiments, wherein the exemplary embodiments and descriptions are provided only for the purpose of illustrating the present invention and are not to be construed as limiting the present invention.

In the detailed embodiment, the high-concurrency internet of things big data communication method based on the intelligent wearable device adopts the following technical scheme:

the system comprises an activation communication protocol, a positioning communication protocol, a setting communication protocol, a function communication protocol, a system communication protocol and an alarm instruction communication protocol; the six types of communication protocols do not influence each other and conflict with each other, and are stored in a storable medium;

the specific traffic flow control of the six major classes of communication protocols is stated below:

as shown in fig. 1, the activation-like communication protocol: when the equipment changes the SIM card every time, the equipment needs to be activated to normally work, and the equipment activation instruction flow activities are as follows: as shown in figure 1 of the drawings, in which,

comprising a memory and a first communication link; at least one memory to implement a first communication link, the first communication link being an active type communication link;

the device sends a 0001 activation instruction, and the server receives the 0001 instruction and judges the 0001 instruction; the server judges whether the instruction is correct, if the instruction is correct, a 0001 confirmation instruction is sent back to the equipment, and the equipment successfully receives the SIM activation; the server judges whether the instruction is correct, if the instruction is incorrect, when the 0001 instruction frequency exceeds the limited frequency, the activation is failed, and the result is correct, and the activation is carried out at this time.

As shown in fig. 2, the positioning-class communication protocol: the method consists of an active positioning protocol and a passive positioning protocol, and the flow activities of the equipment positioning instruction are as follows:

comprising a memory and a second communication link; step two: at least one memory to implement a second communication link, the second communication link being a positioning-type communication link;

sending 0016 a real-time positioning starting instruction, sending 0017 a real-time positioning closing instruction or sending 0018 a primary positioning starting instruction to the equipment; the equipment responds to the fact whether the 0016 real-time positioning starting instruction is received, a 0017 real-time positioning closing instruction is sent or a 0018 primary positioning starting instruction is sent, and if the 0016 real-time positioning closing instruction is received, position data are sent; when three instructions are sent out in the third step, the time interval between the instruction 0016 and the instruction 0017 is judged by the timer; if the GPS satellite data is confirmed, acquiring GPS satellite data, judging whether the GPS data changes between the two instructions, if not, ending, and failing to position; if so, uploading the GPS data and successfully positioning.

As shown in fig. 3, the set-type communication protocol: the method supports the setting of equipment information uploading, heartbeat interval time, working modes, equipment monitoring time periods and the like, and the setting type instruction flow activities are as follows:

comprising a memory and a third communication link; at least one memory to implement a third communication link, the third communication link being a setup-like communication link;

sending an 0006 heartbeat instruction, an 0007 terminal working mode setting instruction, an 0009 monitoring time period device instruction, a 0011 terminal password setting instruction, a 0014 server IP setting instruction and a 0015 APN setting instruction to the device; setting whether to respond; if so, the equipment receives the instruction in the step three and then sends a confirmation instruction of the instruction.

As shown in fig. 4, the functional class communication protocol: which comprises the following steps: the flow activities are as follows:

comprises a memory and a fourth communication link; at least one memory to implement a fourth communication link, the fourth communication link being a functional class communication link;

sending a time control instruction, a 0023 check code instruction or a 0020GPRS line normal monitoring instruction; the equipment responds to the instruction in the third step, and whether the awakening time is up, whether a check code instruction is received or whether a GPRS circuit normal monitoring instruction is received; if the received normal monitoring instruction of the GPRS circuit exceeds three times, the GPRS is restarted; if the command is received, the equipment is awakened, the check code is displayed, and position data, a 0023 confirmation command or a reply 0020 confirmation command are sent;

as shown in fig. 5, the system-like communication protocol: the equipment is correspondingly shut down, factory settings are restored, the dormancy period and other operations are carried out, and the system class instruction flow activities are as follows:

comprises a memory and a fifth communication link; at least one memory to implement a fifth communication link, the fifth communication link being a system-class communication link;

sending a 0021 remote shutdown instruction, a 0100 factory reset instruction or a 0099 hibernation instruction; if the device responds, if the 0021 instruction, the 0100 instruction or the 0099 instruction is confirmed, shutdown is executed, factory equipment is restored or the device enters dormancy.

As shown in fig. 6, the alert command communication protocol: taking the battery power as an example, when the power state of the equipment is abnormal and the equipment cannot support normal work, the alarm information that the battery voltage is too low is sent, and the alarm instruction flow activity is as follows:

comprises a memory and a sixth communication link; at least one memory to implement a sixth communication link, the sixth communication link being an alarm instruction communication link;

detecting the electric quantity, and sending a low-voltage alarm when the voltage of the battery is too low; and if the battery voltage is normal, ending the detection.

The above description is only a preferred embodiment of the present invention, and all equivalent changes or modifications of the structure, characteristics and principles described in the present invention are included in the scope of the present invention.

Claims (1)

1. A high-concurrency Internet of things big data communication method based on intelligent wearable equipment is characterized by comprising the following steps: the technical scheme is as follows:

the system comprises an activation communication protocol, a positioning communication protocol, a setting communication protocol, a function communication protocol, a system communication protocol and an alarm instruction communication protocol; the six types of communication protocols do not influence each other and conflict with each other, and are stored in a storable medium;

activation-type communication protocol: when the equipment changes the SIM card every time, the equipment needs to be activated to normally work, and the equipment activation instruction flow activities are as follows:

the method comprises the following steps: comprising a memory and a first communication link;

step two: at least one memory to implement a first communication link, the first communication link being an active type communication link;

step three: the device sends a 0001 activation instruction, and the server receives the 0001 instruction and judges the 0001 instruction;

step four: the server judges whether the instruction is correct, if so, the server sends a returned 0001 confirmation instruction to the equipment, and the equipment successfully receives the SIM activation;

step five: the server judges whether the instruction is correct, if the instruction is incorrect, when the 0001 instruction frequency exceeds the limited frequency, the activation is failed;

positioning type communication protocol: the method consists of an active positioning protocol and a passive positioning protocol, and the flow activities of the equipment positioning instruction are as follows:

the method comprises the following steps: comprising a memory and a second communication link;

step two: at least one memory to implement a second communication link, the second communication link being a positioning-type communication link;

step three: sending 0016 a real-time positioning starting instruction, sending 0017 a real-time positioning closing instruction or sending 0018 a primary positioning starting instruction to the equipment;

step four: judging whether the equipment receives the instruction or not according to the instruction in the step three; when the equipment receives a 0016 real-time positioning starting instruction, the equipment starts real-time positioning and sends position data;

then judging whether a 0017 instruction is received, if the 0017 instruction is not received, continuing to send position data, and if the 0017 instruction is received, closing the real-time positioning; when the equipment receives a 0017 real-time positioning closing instruction, the equipment closes real-time positioning and sends a 0017 confirmation instruction;

when the equipment receives 0018 starting one-time positioning instruction, the equipment responds to the positioning instruction and sends position data;

step five: when an instruction 0016, an instruction 0017 and an instruction 0018 are sent in the third step, a timer judges whether the time interval between the instruction 0016 and the instruction 0017 is reached, if the time interval is not reached, timing is continued, if the time interval is not reached, a GPS satellite signal is obtained to further obtain GPS satellite data, whether the GPS satellite data is changed is judged, if the GPS satellite data is changed, the GPS data is uploaded, and if the GPS satellite data is not changed, the process is ended;

setting a communication protocol: the method supports the setting of equipment information uploading, heartbeat interval time, a working mode and equipment monitoring time periods, and comprises the following steps of:

the method comprises the following steps: comprising a memory and a third communication link;

step two: at least one memory to implement a third communication link, the third communication link being a setup-like communication link;

step three: sending an 0006 heartbeat instruction, an 0007 terminal working mode setting instruction, an 0009 monitoring time period device instruction, a 0011 terminal password setting instruction, a 0014 server IP setting instruction and a 0015 APN setting instruction to the device;

step four: for the instruction in the third step, whether the equipment receives the instruction or not is judged; if the equipment receives the instruction, executing the instruction and sending a confirmation instruction of the instruction;

function type communication protocol: the process activities are as follows:

the method comprises the following steps: comprises a memory and a fourth communication link;

step two: at least one memory to implement a fourth communication link, the fourth communication link being a functional class communication link;

step three: sending a time control instruction, a 0023 check code instruction or a 0020GPRS line normal monitoring instruction;

step four: the equipment responds to the instruction in the third step, and judges whether the awakening time is up, whether a check code instruction is received or whether a GPRS circuit normal monitoring instruction is received; if the normal monitoring instruction of the GPRS circuit is not received for more than three times, the GPRS is restarted;

step five: if the awakening time is up, awakening the equipment and sending position data, if a check code instruction is received, displaying the check code and sending a 0023 confirmation instruction, and if a GPRS line normal detection instruction is received, replying a 0020 confirmation instruction;

system-class communication protocol: corresponding operations are carried out on equipment shutdown, factory reset and a dormancy period, and system class instruction flow activities are as follows:

the method comprises the following steps: comprises a memory and a fifth communication link;

step two: at least one memory to implement a fifth communication link, the fifth communication link being a system-class communication link;

step three: sending a 0021 remote shutdown instruction, a 0100 factory reset instruction or a 0099 hibernation instruction;

step four: if the equipment receives the 0021 instruction or the 0100 instruction, the equipment returns to confirm the 0021 instruction or confirm the 0100 instruction and shuts down or restores the factory equipment; if the device receives 0099 instruction, the device enters dormancy;

alarm command communication protocol: when the battery power is too low and cannot support normal work, alarm information that the battery voltage is too low is sent, and alarm instruction flow activities are as follows:

the method comprises the following steps: comprises a memory and a sixth communication link;

step two: at least one memory to implement a sixth communication link, the sixth communication link being an alert instruction communication link;

step three: detecting the electric quantity, and sending a low-voltage alarm when the voltage of the battery is too low; and if the battery voltage is normal, ending the detection.

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