KR102658009B1 - A method for NOTIFYING DISASTER SITUATIONS BASED ON a CROSS TECHNOLOGY COMMUNICATION and SYSTEM supporting the same - Google Patents

Abstract

This specification provides a method for notifying disaster situations based on heterogeneous communication.
More specifically, receiving, by a second communication device, an access frame used for heterogeneous communication from a transmitting first communication device in a heterogeneous communication mode; Broadcasting the access frame to the transmitting first communication device and the receiving first communication device in a broadcast bypass mode; Receiving a data frame used for heterogeneous communication from the transmitting first communication device in the heterogeneous communication mode; and broadcasting the data frame to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode.
This has the effect of expanding the range of a communication network composed of heterogeneous communication devices, allowing more rapid response to disaster situations.

Description

Heterogeneous communication-based disaster situation notification method and system supporting the same {A method for NOTIFYING DISASTER SITUATIONS BASED ON a CROSS TECHNOLOGY COMMUNICATION and SYSTEM supporting the same}

This specification relates to a disaster situation notification method, and more specifically, to a heterogeneous communication-based disaster situation notification method and a system to support the same.

Wi-Fi communication and ZigBee communication have different communication standards of WLAN and WPAN, respectively, in the 2.4 GHz ISM band.

Existing ad-hoc heterogeneous communication technology used communication devices equipped with Wi-Fi and ZigBee modules.

However, the existing method uses a coexistence method that allocates white space for each other's standard performance, which does not provide a data exchange method for the two communication standards.

ZigBee communication and Wi-Fi communication use the same frequency band, but because their communication methods are different, a problem arises where data interpretation between different standards is impossible.

In addition, the existing ad-hoc heterogeneous communication technology requires analysis up to the application layer to exchange data by combining Wi-Fi communication and ZigBee communication to change WLAN standard data to WPAN standard data. However, this has the problem that complex encoding and decoding are performed.

Therefore, the purpose of this specification is to provide a method for transmitting and receiving disaster messages based on heterogeneous communication by assigning roles to relay nodes of transmission and reception communication devices operating in different standards.

More specifically, 2-hop neighbors WLAN (Wi-Fi) standard wireless communication devices can communicate communication problems of relay nodes and infrastructure structures through heterogeneous communication with adjacent WPAN (ZigBee) standard wireless communication devices. .

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

This specification relates to a method for notifying a disaster situation based on heterogeneous communication between a first communication device using a first wireless communication technology and a second communication device using a second wireless communication technology, by the second communication device. The performed method includes receiving an access frame used for heterogeneous communication from a transmitting first communication device in a heterogeneous communication mode; Broadcasting the access frame to the transmitting first communication device and the receiving first communication device in a broadcast bypass mode; Receiving a data frame used for heterogeneous communication from the transmitting first communication device in the heterogeneous communication mode; and broadcasting the data frame to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode, wherein the data frame includes control information indicating the type of the disaster situation, and , the heterogeneous communication mode is activated when the value of the heterogeneous communication setting field included in the access frame is '1', and the broadcast bypass mode is activated when the value of the broadcast bypass setting field included in the data frame is '1'. It is characterized as being activated when it is '1'.

In addition, in this specification, the access frame and the data frame include at least one symbol, and the at least one symbol is characterized in that it consists of a frame and DIFS (Distributed Inter Frame Space) having the same time interval.

Additionally, in this specification, the data frame is characterized as including a start symbol, a data symbol, and an end symbol.

Additionally, in this specification, the data symbols included in the data frame are characterized in that they include the control information.

Additionally, in this specification, the control information is characterized as consisting of a symbol set including three symbols.

Additionally, in this specification, the type of disaster situation is characterized in that it is classified according to the value of the symbol set.

Additionally, in this specification, the type of disaster situation is characterized as a typhoon, avalanche, landslide, or fire.

Additionally, in this specification, when the value of the symbol set is 111, the type of disaster situation is a typhoon, and when the value of the symbol set is 101, the type of disaster situation is an avalanche, and the value of the symbol set is 110. In this case, the type of disaster situation is a landslide, and if the value of the symbol set is 011, the type of disaster situation is fire.

Additionally, in this specification, the access frame by the first transmitting communication device is characterized in that it is transmitted when the SRC (short retry count) value satisfies 6.

Additionally, in this specification, the heterogeneous communication setting field is characterized as being the reserved first bit value of the reason code.

Additionally, in this specification, reception of an access frame by the second communication device is characterized in that it is performed when a packet error related to the second wireless communication technology occurs in the second communication device.

Additionally, in this specification, the heterogeneous communication mode and the broadcast bypass mode are characterized in that they are deactivated when the data frame stored in the transmitting first communication device and the data frame received from the second communication device are the same.

Additionally, in this specification, the stored data frame is characterized as a data frame received by the second communication device from the first communication device.

Additionally, in this specification, the first wireless communication technology is Wi-Fi communication technology, and the second wireless communication technology is Zigbee communication technology.

In addition, in this specification, the broadcast bypass mode is characterized as a mode in which signals received from the outside are transmitted to the outside as is.

In addition, this specification provides a second communication device for notifying a disaster situation based on heterogeneous communication between a first communication device using a first wireless communication technology and a second communication device using a second wireless communication technology, RF module for transmitting and receiving signals; Memory; and a processor functionally connected to the RF module and memory, wherein the processor receives an access frame used for heterogeneous communication from a transmitting first communication device in a heterogeneous communication mode; broadcasting the access frame to the transmitting first communication device and the receiving first communication device in a broadcast bypass mode; receiving a data frame used for heterogeneous communication from the transmitting first communication device in the heterogeneous communication mode; and controlling the data frame to be broadcast to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode, wherein the data frame includes control information indicating the type of the disaster situation, The heterogeneous communication mode is activated when the value of the heterogeneous communication setting field included in the access frame is '1', and the broadcast bypass mode is activated when the value of the broadcast bypass setting field included in the data frame is '1'. It is characterized as being activated in the case of '.

This specification expands the range of communication networks through the cross-communication technology (CTC) of the IEEE 802.11 standard and IEEE 802.15.4 or heterogeneous communication technologies to prevent disasters by receiving simple bit information in disaster situations and exchanging disaster information between heterogeneous communication devices. It has the effect of preventing secondary damage caused by the situation.

The effects that can be obtained from the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description below. .

The accompanying drawings, which are included as part of the detailed description to aid understanding of the present invention, provide embodiments of the present invention, and together with the detailed description, explain technical features of the present invention.
FIG. 1A is a diagram showing an example of a symbol data format proposed in this specification, and FIG. 1B is a diagram showing an example of a CTC-access symbol configuration proposed in this specification.
Figure 2 is a diagram showing an example of the CTC-data symbol configuration proposed in this specification.
Figure 3 is a flowchart showing an example of a communication method between heterogeneous communications proposed in this specification.
Figure 4 is a flowchart showing an example of a method of operating a communication device for notifying a disaster situation based on heterogeneous communication proposed in this specification.
Figure 5 illustrates a block diagram of a communication device to which the methods proposed in this specification can be applied.

It should be noted that the technical terms used in this specification are only used to describe specific embodiments and are not intended to limit the spirit of the technology disclosed in this specification. In addition, the technical terms used in this specification, unless specifically defined in a different way in this specification, should be interpreted as meanings generally understood by those skilled in the art in the field to which the technology disclosed in this specification belongs. It should not be interpreted in a very comprehensive sense or in an excessively reduced sense. In addition, if the technical term used in this specification is an incorrect technical term that does not accurately express the idea of the technology disclosed in this specification, it is a technical term that can be correctly understood by a person with ordinary knowledge in the field to which the technology disclosed in this specification belongs. It should be understood and replaced with . Additionally, general terms used in this specification should be interpreted as defined in the dictionary or according to the context, and should not be interpreted in an excessively reduced sense.

Terms containing ordinal numbers, such as first, second, etc., used in this specification may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component without departing from the scope of the present invention.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

Additionally, when describing the technology disclosed in this specification, if it is determined that a detailed description of a related known technology may obscure the gist of the technology disclosed in this specification, the detailed description will be omitted. In addition, it should be noted that the attached drawings are only intended to facilitate easy understanding of the spirit of the technology disclosed in this specification, and should not be construed as limiting the spirit of the technology by the attached drawings.

Hereinafter, we will look at the disaster situation response notification method based on heterogeneous communication technology proposed in this specification.

This specification presents a data transmission and reception method for WLAN (Wireless Local Area Network) communication and WPAN (Wireless Personal Area Network) communication and a series of processes performed in a communication device, thereby implementing the WLAN standard, which is a 2-hop neighbor. It provides a two-way communication method for communication devices to send and receive messages related to disaster response through communication devices implementing the WPAN standard, enabling transmission of data related to disaster situations using communication devices of heterogeneous communication standards.

In addition, this specification uses a broadcast bypass mode in which a relay node using a WPAN communication device directly transmits the signal received from the WLAN communication device without complex encoding or decoding (i.e., a type of repeater) ) is used like ). Here, the signal transmitted through the WPAN is used like a data signal and an ACK signal in a WLAN communication device.

In addition, this specification is a method of detecting each slot in a unipolar RZ (Return-to-Zero) method through energy detection of a WLAN signal that transmits the beacon interval as data in a WPAN communication device. It is transmitted back to other Wi-Fi devices through a ZigBee device to deliver disaster situation notifications to nearby Wi-Fi devices.

At this time, the ZigBee device transmits the signal in the same configuration and method as the signal transmitted by the Wi-Fi device, thereby reducing overhead because it does not require decoding of the signal received from the Wi-Fi device.

In addition, in this specification, frame time and DIFS (Distributed Inter Frame Space) are unified and defined as 2.112ms for two-way communication between Wi-Fi devices and ZigBee devices.

Equation 1 below is the formula for calculating DIFS.

ASIFSTime is 12symbols/(62500symbols/sec), and aSlotTime is calculated as Equation 2 below.

In addition, this specification configures the start bit and end bit sets of data so that it can be known how long the data of the disaster signal will be transmitted during heterogeneous communication, and CTC (Cross Technology) is used to transmit and receive data in the Unipolar RZ method. Communication)-transmission and CTC-reception modes are provided.

Hereinafter, we will look in more detail at the heterogeneous communication-based disaster situation response notification method proposed in this specification.

First, let's look at the CTC setup process.

For CTC setup, (i) CTC setup flag and (ii) CTC activation mode are defined.

The CTC setup flag can be set using 1 bit of the reserved field of the reason code. For example, if the 1-bit value of the reserved field of the reason code is '1', it may mean that CTC is set up, that is, the CTC activation mode is 'On', and the 1-bit value of the reserved field of the reason code is '1'. If '0', this may mean that CTC is not set up, that is, the CTC activation mode is 'Off', and the interpretation of the 1-bit value of the reserved field may be reversed.

CTC activation mode may mean changing the control parameters of the Wi-Fi communication device.

In other words, set the transmission power of the Wi-Fi communication device to maximum, set the frame time to 2.112ms, and set DIFS to 2.112ms.

Here, one unit symbol mentioned in this specification consists of a frame and DIFS, and the symbol can be interpreted in a unipolar Return-to-Zero (RZ) method.

As seen, the frame time and DIFS time are the same at 2.112ms.

The symbol configuration transmitted in CTC active mode may include (i) CTC-Access symbol and (ii) CTC-Data symbol.

Next, we will look at the Broadcast Bypass setup process.

For broadcast bypass setup, (1) Broadcast Bypass setup Flag and (2) Broadcast Bypass activation mode are defined.

The broadcast bypass setup flag can use 1 bit of a newly defined field or a previously unused reserved field.

Therefore, if the value of the broadcast bypass setup flag is '1', it may mean that the broadcast bypass is set up, that is, the broadcast bypass activation mode is 'On', and the broadcast bypass setup flag If the value of is '0', it may mean that the broadcast bypass is not set up, that is, the broadcast bypass activation mode is 'Off', and it can also be interpreted as the opposite case.

Additionally, in the broadcast bypass activation mode, (the Wi-Fi communication device) can store the received symbol as a parameter and transmit the stored parameter.

FIG. 1A is a diagram showing an example of the symbol data format proposed in this specification, FIG. 1B shows an example of the CTC-access symbol configuration proposed in this specification, and FIG. 2 is a CTC-data symbol configuration proposed in this specification. Shows an example.

In Figure 1, the hatched portion 110 represents a frame, and the transparent portion 120 represents DIFS.

In Figure 1a, when the frame and DIFS value is 10, the symbol value becomes '1' according to the unipolar RZ method, and when the frame and DIFS value is 00, the symbol value becomes '0' according to the unipolar RZ method. In this specification, since the unipolar method is applied to the interpretation of symbol values, the frame and DIFS values cannot be 01 or 11. If the values are generated due to reasons such as missynchronization or poor access, they are 10 or 00. Initialization and access can proceed again until this is detected. In Figure 1, a symbol unit includes one frame and one DIFS.

Referring to Figure 1b, it can be seen that the CTC-Access symbol consists of 5 symbols with a value of 1.

Referring to FIG. 2, the CTC-data symbol may be composed of a start symbol, a data symbol, and an end symbol.

Here, the start symbol may be set to the value '1000' consisting of one frame and three consecutive DIFS, and the end symbol may consist of two consecutive DIFS, one frame, and one DIFS following it. It can be set to the value '0010'.

Table 1 below is a table showing an example of a symbol configuration set of data symbols according to disaster situations proposed in this specification.

Detection location symbol 0 symbol 1 symbol 2 Message content data One One One Disaster situation caused by typhoon One 0 One Disaster situation due to avalanche One One 0 Disaster situation caused by landslide 0 One One Disaster situation caused by fire

The symbol values in Table 1 are values included in the data symbol area of FIG. 2. When the data symbol in FIG. 2 is '111' in Table 1, it represents a disaster situation caused by a typhoon, and the data symbol in FIG. 2 is the value in Table 1. In the case of '110', it may indicate a disaster situation caused by a landslide. This is an example, and the data symbol value may be set to a different value depending on the type of disaster situation.

How to perform heterogeneous communication

Hereinafter, based on the information discussed above, we will look in detail at how to perform heterogeneous communication between a Wi-Fi communication device and a Zigbee communication device.

First, the Wi-Fi communication device periodically checks the SRC to check whether the SRC (Short Retry Count) value is 6.

Here, the reason for setting SRC to 6 is to detect that there is a communication problem with the Wi-Fi relay node. Since ACK frames cannot be received continuously, SRC is set to 6, which is the maximum value.

When the SRC is 6 and the CTC-setup flag of the Wi-Fi communication device is set to '1' (i.e., when the CTC activation mode is 'On'), the Wi-Fi communication device performs a random time backoff ( or random backoff) and then check whether a CTC-access frame is detected.

The CTC-setup flag may use the 1st bit of the reserved field of the reason code.

Here, the reason for setting the random time backoff is to prevent Wi-Fi communication devices that have communication problems from transmitting at the same time, and the random time backoff setting value between each Wi-Fi communication device can be set differently. there is.

A Wi-Fi communication device that fails to detect the CTC-access frame (hereinafter referred to as a 'transmitting Wi-Fi communication device') transmits a CTC-access frame to a Zigbee communication device.

Here, the reason for transmitting the CTC-access frame to the ZigBee communication device is to periodically transmit the CTC-access frame, causing a packet error in the Zigbee communication device, and the Zigbee communication device detects the CTC-access frame. It is for the purpose of doing so.

The Wi-Fi communication device that detects the CTC-access frame (hereinafter referred to as 'receiving Wi-Fi communication device') receives the CTC-data frame.

The ZigBee communication device checks whether an error related to packet transmission and reception occurred due to the CTC-access frame.

If an error related to packet transmission/reception does not occur, the Wi-Fi communication device starts again with the procedure of transmitting a CTC-access frame to the ZigBee communication device.

When an error related to packet transmission and reception occurs, the ZigBee communication device broadcasts the received CTC-access frame to the Wi-Fi communication device in broadcast bypass mode.

In this specification, broadcast bypass means a method of transmitting data to the outside in the same way as data received from the outside. In other words, broadcast bypass refers to a transmission method that transmits data received from the outside to the outside as is without any change, transformation, or modification.

Here, when a packet error occurs due to the CTC-access frame, the Zigbee communication device performs carrier detection to check whether the signal is for heterogeneous communication. Here, the broadcast bypass setup flag of the ZigBee communication device is activated (eg, set to '1').

That is, in the broadcast bypass activation mode, the ZigBee communication device broadcasts the symbols received from the transmitting Wi-Fi communication device as is, and thus broadcasts the CTC-access frame as is without a separate process.

Here, the Wi-Fi communication device that transmits the CTC-access frame is a transmitting Wi-Fi communication device, and the Wi-Fi communication device that does not transmit the CTC-access frame is a receiving Wi-Fi communication device.

Additionally, in the broadcast bypass activation mode, the transmitting Wi-Fi communication device may determine that access is completed through decoding of a CTC-access frame, and the receiving Wi-Fi communication device may determine that access is completed through the transmitting Wi-Fi communication device. Carrier detection begins to receive CTC-data frames from the device.

Then, the transmitting Wi-Fi communication device checks whether a reception error has occurred for the CTC-access frame transmitted from the Zigbee communication device (that is, it checks whether detection of the CTC-access frame has failed).

If a reception error for the CTC-access frame occurs, the transmitting Wi-Fi communication device starts again with the procedure of transmitting the CTC-access frame to the ZigBee communication device.

If a reception error for the CTC-access frame does not occur, the transmitting Wi-Fi communication device transmits a CTC-data frame to the ZigBee communication device.

Here, the transmitting Wi-Fi communication device stores the transmitted CTC-data frame in parameters and compares the stored parameters with the CTC-data frame received in the future to check whether they are the same.

Then, the ZigBee communication device checks whether a reception error for the CTC-data frame has occurred.

If a reception error for the CTC-data frame does not occur, the transmitting Wi-Fi communication device starts again with the procedure of transmitting a CTC-access frame to the ZigBee communication device.

When a reception error for the CTC-data frame occurs, the Zigbee communication device broadcasts the received CTC-data frame to the Wi-Fi communication device.

In addition, the Wi-Fi communication device checks whether a reception error occurs in the CTC-data frame transmitted from the ZigBee communication device.

If a reception error for the CTC-data frame occurs, the Wi-Fi communication device starts again with the procedure of transmitting a CTC-access frame to the ZigBee communication device.

If a reception error for the CTC-data frame does not occur, the transmitting Wi-Fi device determines whether the CTC-data frame transmitted by the transmitting Wi-Fi and the CTC-data frame transmitted by the ZigBee communication device are the same. judge.

As a result of the determination, if the two CTC-data frames are the same, the Wi-Fi communication device determines that the CTC-data frame has been successfully bypassed broadcast through the ZigBee communication device.

If, as a result of the determination, the two CTC-data frames are not identical, the transmitting Wi-Fi communication device starts again with the procedure of transmitting a CTC-access frame to the ZigBee communication device.

Thereafter, the receiving Wi-Fi communication device that receives the CTC-data frame decodes the CTC-data frame and receives an emergency message, and the transmitting Wi-Fi communication device and the ZigBee communication device use the CTC-setup flag, broadcast The existing communication method will be performed until the cast bypass setup flag is set to active again.

Figure 3 is a flowchart showing an example of a communication method between heterogeneous communications proposed in this specification.

Referring to FIG. 3, the transmitting Wi-Fi communication device transmits a CTC (Cross Technical Communication)-access frame to the Zigbee communication device in CTC activation mode (S310). The CTC activation mode may be when the CTC-setup flag is set to '1'.

Then, the ZigBee communication device broadcast bypasses the CTC-access frame to the transmitting Wi-Fi communication device and the receiving Wi-Fi communication device in the broadcast bypass activation mode (S320).

The broadcast bypass activation mode may be when the broadcast bypass setup flag is set to '1'.

Then, the transmitting Wi-Fi communication device transmits a CTC-data frame to the ZigBee communication device (S330).

Then, the ZigBee communication device broadcasts and bypasses the CTC-data frame to the transmitting Wi-Fi communication device and the receiving Wi-Fi communication device (S340).

Figure 4 is a flowchart showing an example of a method of operating a communication device for notifying a disaster situation based on heterogeneous communication proposed in this specification.

That is, Figure 4 shows a disaster situation based on heterogeneous communication between a first communication device using a first wireless communication technology (e.g., Wi-Fi) and a second communication device using a second wireless communication technology (e.g., Zigbee). It is about a way to inform.

First, the second communication device receives an access frame used for heterogeneous communication from the first transmitting communication device in heterogeneous communication mode (S410).

The access frame by the first transmitting communication device can be transmitted when the SRC (short retry count) value satisfies 6.

Here, the SRC has a maximum value of 6, and this value represents the number of times a retransmission problem occurred.

The heterogeneous communication mode can be activated when the value of the heterogeneous communication setting field included in the access frame is '1' or 'active state'.

The heterogeneous communication setting field may use the reserved first bit value of the reason code.

Reception of the access frame by the second communication device may be performed when a packet error related to the second wireless communication technology occurs in the second communication device.

Then, the second communication device broadcasts the access frame to the first transmitting communication device and the first receiving communication device in broadcast bypass mode (S420).

Then, the second communication device receives a data frame used for heterogeneous communication from the first transmitting communication device in the heterogeneous communication mode (S430).

The broadcast bypass mode can be activated when the value of the broadcast bypass setting field included in the data frame is '1' or 'active state'.

The access frame and the data frame include at least one symbol, and the at least one symbol may be composed of a frame having the same time interval and a Distributed Inter Frame Space (DIFS).

The data frame includes control information indicating the type of disaster situation.

The data frame includes a start symbol, a data symbol, and an end symbol, and the data symbol included in the data frame may include the control information.

The control information consists of a symbol set including three symbols, and the type of disaster situation can be classified according to the value of the symbol set.

The type of disaster situation may be a typhoon, avalanche, landslide, fire, etc.

For example, if the value of the symbol set is 111, the type of disaster situation is typhoon, if the value of the symbol set is 101, the type of disaster situation is avalanche, and the value of the symbol set is 110. In this case, the type of disaster situation may be a landslide, and if the value of the symbol set is 011, the type of disaster situation may be fire.

Then, the second communication device broadcasts the data frame to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode (S440).

Here, the heterogeneous communication mode and the broadcast bypass mode may be deactivated when the data frame stored in the transmitting first communication device and the data frame received from the second communication device are the same.

The stored data frame may be a data frame received by the second communication device from the first communication device.

General equipment to which the present invention can be applied

Figure 5 illustrates a block diagram of a communication device to which the methods proposed in this specification can be applied.

The wireless communication system includes a Wi-Fi communication device, a Zigbee communication device, etc., and the Wi-Fi communication device includes a transmitting Wi-Fi communication device and a receiving Wi-Fi communication device.

The communication device 10 includes a processor (12), a memory (13), and an RF module (radio frequency module, 11). The processor implements the functions, processes and/or methods previously proposed in FIGS. 1 to 4. The layers of the air interface protocol may be implemented by a processor. Memory is connected to the processor and stores various information to run the processor. The RF module is connected to the processor and transmits and/or receives wireless signals.

The embodiments described above combine the components and features of the present invention in a predetermined form. Each component or feature should be considered optional unless explicitly stated otherwise. Each component or feature may be implemented in a form that is not combined with other components or features. Additionally, it is possible to configure an embodiment of the present invention by combining some components and/or features. The order of operations described in embodiments of the present invention may be changed. Some features or features of one embodiment may be included in other embodiments or may be replaced with corresponding features or features of other embodiments. It is obvious that claims that do not have an explicit reference relationship in the patent claims can be combined to form an embodiment or included as a new claim through amendment after filing.

Embodiments according to the present invention may be implemented by various means, for example, hardware, firmware, software, or a combination thereof. In the case of hardware implementation, an embodiment of the present invention includes one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), and FPGAs ( It can be implemented by field programmable gate arrays, processors, controllers, microcontrollers, microprocessors, etc.

In the case of implementation by firmware or software, an embodiment of the present invention may be implemented in the form of a module, procedure, function, etc. that performs the functions or operations described above. Software code can be stored in memory and run by a processor. The memory is located inside or outside the processor and can exchange data with the processor through various known means.

It is obvious to those skilled in the art that the present invention can be embodied in other specific forms without departing from the essential features of the present invention. Accordingly, the above detailed description should not be construed as restrictive in all respects and should be considered illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

10: Communication device

Claims (20)

A method for notifying a disaster situation based on heterogeneous communication between a first communication device using a first wireless communication technology and a second communication device using a second wireless communication technology, the method being performed by the second communication device silver,
Receiving an access frame used for heterogeneous communication from a transmitting first communication device in a heterogeneous communication mode;
Broadcasting the access frame to the transmitting first communication device and the receiving first communication device in a broadcast bypass mode;
Receiving a data frame used for heterogeneous communication from the transmitting first communication device in the heterogeneous communication mode; and
Broadcasting the data frame to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode,
The data frame includes control information indicating the type of disaster situation,
The heterogeneous communication mode is activated when the value of the heterogeneous communication setting field included in the access frame is '1', and
The broadcast bypass mode is activated when the value of the broadcast bypass setting field included in the data frame is '1'. According to claim 1,
The access frame and the data frame include at least one symbol,
A method characterized in that the at least one symbol is composed of frames and DIFS (Distributed Inter Frame Space) having the same time interval. According to clause 2,
The data frame includes a start symbol, a data symbol, and an end symbol,
The method wherein the data symbol includes the control information. According to clause 3,
A method characterized in that the control information consists of a symbol set including three symbols. According to clause 4,
A method characterized in that the type of disaster situation is classified according to the value of the symbol set. According to clause 5,
A method wherein the type of disaster situation is a typhoon, avalanche, landslide or fire. According to clause 6,
If the value of the symbol set is 111, the type of disaster situation is a typhoon,
If the value of the symbol set is 101, the type of disaster situation is avalanche,
If the value of the symbol set is 110, the type of disaster situation is landslide,
When the value of the symbol set is 011, the type of disaster situation is fire. According to claim 1,
A method characterized in that the access frame by the first transmitting communication device is transmitted when the SRC (short retry count) value satisfies 6. According to claim 1,
A method wherein the heterogeneous communication setting field is a reserved first bit value of a reason code. According to claim 1,
A method characterized in that reception of an access frame by the second communication device is performed when a packet error related to the second wireless communication technology occurs in the second communication device. According to claim 1,
Wherein the heterogeneous communication mode and the broadcast bypass mode are deactivated when a data frame stored in the transmitting first communication device and a data frame received from the second communication device are the same. According to claim 11,
The method wherein the stored data frame is a data frame received by the second communication device from the first communication device. According to claim 1,
The first wireless communication technology is Wi-Fi communication technology, and the second wireless communication technology is Zigbee communication technology. According to claim 1,
The broadcast bypass mode is a mode in which signals received from the outside are transmitted to the outside as is. In the second communication device for reporting a disaster situation based on heterogeneous communication between a first communication device using a first wireless communication technology and a second communication device using a second wireless communication technology,
RF module for transmitting and receiving wireless signals;
Memory; and
Includes a processor functionally connected to the RF module and memory, wherein the processor includes,
Receiving an access frame used for heterogeneous communication from a transmitting first communication device in a heterogeneous communication mode;
broadcasting the access frame to the transmitting first communication device and the receiving first communication device in a broadcast bypass mode;
receiving a data frame used for heterogeneous communication from the transmitting first communication device in the heterogeneous communication mode; and
Controlling the data frame to be broadcast to the transmitting first communication device and the receiving first communication device in the broadcast bypass mode,
The data frame includes control information indicating the type of disaster situation,
The heterogeneous communication mode is activated when the value of the heterogeneous communication setting field included in the access frame is '1', and
The broadcast bypass mode is activated when the value of the broadcast bypass setting field included in the data frame is '1'. According to claim 15,
The data frame includes a start symbol, a data symbol, and an end symbol,
A communication device, characterized in that the data symbols included in the data frame include the control information. According to claim 16,
The control information consists of a symbol set including three symbols,
A communication device, characterized in that the type of disaster situation is classified according to the value of the symbol set. According to claim 15,
A communication device, characterized in that the access frame by the transmitting first communication device is transmitted when the SRC (short retry count) value satisfies 6. According to claim 15,
A communication device, characterized in that reception of an access frame by the second communication device is performed when a packet error related to the second wireless communication technology occurs in the second communication device. According to claim 15,
The heterogeneous communication mode and the broadcast bypass mode are deactivated when a data frame stored in the transmitting first communication device and a data frame received from the second communication device are the same.