KR102078903B1 - reliable data checking method of wireless encrypted communication - Google Patents

Abstract

According to the present invention, when the wireless communication device is directly connected to a wireless communication source and a receiving communication device, the encrypted synchronization signal and data having a frame structure sent by the calling communication device are decrypted by the receiving communication device. In accordance with the determination of the error of the synchronization signal and data, to provide reliable wireless encryption communication between the transmission and reception,
According to the present invention, a reliable data determination method of wireless encryption communication includes an encrypted synchronization signal and data having a frame structure sent by the calling party communication device when wirelessly communicating with each other directly in a wirelessly connected calling party and receiving party. After decoding at the receiving side communication apparatus, there is a remarkable effect of providing reliable wireless encryption communication between the transmission and reception by determining the error of the synchronization signal and data.

Description

Reliable data checking method of wireless encrypted communication

The present invention relates to a reliable data determination method of wireless cryptographic communication, and more particularly, a frame structure sent by the calling party communication device when wirelessly communicating with each other in a wireless direct communication device and a receiving communication device. The present invention relates to a reliable data determination method of wireless encryption communication, which provides reliable wireless encryption communication between transmission and reception by determining an error of the synchronization signal and data after decrypting the encrypted synchronization signal and data with the receiving side communication apparatus.

In general, in the case of wireless communication, it is possible that data sent from the calling party is lost when random data arrives at the receiving party, and the receiving party may receive encrypted data having a lost frame structure. If you receive encrypted data, you must re-request.

A prior art wireless encryption method using GFS time synchronization of Korean Patent Laid-Open Publication No. 10-2016-0117366, comprising: generating a cipher text by encrypting plain text received from a professional communication terminal; Generating random number data; Transmitting a bitstream consisting of the cipher text and the random number data; And a step of outputting data by changing a channel according to the GPS time synchronization and the random number value, wherein generating the cipher text includes inserting a sync frame before the cipher text, wherein the sync frame includes the random data. And key information used to decrypt the cipher text and a sync pattern for distinguishing the cipher text, wherein the key information is generated by error correction encoding random number and time information, and generates a channel according to the GPS time synchronization and the random number value. In the changing and outputting data, time data synchronized with the GPS time is used as the source data to generate a time value by applying a preset variable condition to the source data, and according to the generated time value and the random number value. The process of changing data and outputting data is included. A process of generating a random number data synchronized with the random number data generation in the step of generating the random number data and generating a time value identical to the time value based on the GPS time through the same condition as the variable condition. It is described as a wireless encryption method using GPS time synchronization, characterized in that it is possible to decrypt the received modulated data included.

In another prior art, a method and apparatus for encrypting over-the-air communication in a wireless communication system of Korean Patent Publication No. 10-0915769, comprising: receiving a plurality of symbols in a method for encrypting a wireless transmission; step; Shifting a phase of each symbol of the plurality of symbols to generate a plurality of phase shifted symbols; Modulating each phase shifted symbol of the plurality of phase shifted symbols into an orthogonal subcarrier to produce at least one modulated subcarrier; And transmitting the at least one modulated subcarrier over a wireless link, wherein the shifting step comprises both an apparatus for transmitting the plurality of phase shifted symbols and an apparatus for receiving the plurality of phase shifted symbols. It is described as a wireless transmission encryption method which includes shifting the phase of each symbol of the plurality of symbols based on one code word of the plurality of code words, which is known to.

However, the conventional configuration described above has a disadvantage in that reliability is insufficient when an error occurs in data received from a receiving side communication apparatus after transmitting encrypted data through wireless communication.

Therefore, through the wireless data communication method of the present invention, an encrypted synchronization having a frame structure sent by the calling party communication device when wirelessly communicating with each other in a wirelessly connected source communication device and a receiving communication device. The present invention provides a reliable data determination method of wireless cryptographic communication that decodes a signal and data at a receiving side communication apparatus, and then determines an error of a synchronization signal and data to provide reliable wireless encrypted communication between transmission and reception.

According to the present invention, when the wireless communication device is directly connected to a wireless communication source and a receiving communication device, the encrypted synchronization signal and data having a frame structure sent by the calling communication device are decrypted by the receiving communication device. In accordance with the error determination of the synchronization signal and data, it characterized in that to provide reliable wireless encryption communication between the transmission and reception.

According to the present invention, a reliable data determination method of wireless encryption communication includes an encrypted sync signal and data having a frame structure sent by the calling party communication device when wirelessly communicating with each other directly in the wireless communication device. After decoding at the receiving side communication apparatus, there is a remarkable effect of providing reliable wireless encryption communication between the transmission and reception by determining the error of the synchronization signal and data.

1 is a conceptual diagram of the first and second error determination of the reliable data determination method of the present invention wireless encryption communication
2 is a conceptual view illustrating a request for primary error determination in a reliable data determination method of the present invention wireless crypto communication.
3 to 4 is a conceptual view of request implementation for the second error determination of the reliable data determination method of the present invention wireless encryption communication

According to the present invention, when the wireless communication is directly performed by the transmitting and receiving communication apparatus directly connected wirelessly, the encrypted communication signal and data having a frame structure sent by the calling communication apparatus are decrypted by the receiving communication apparatus. In accordance with the error determination of the synchronization signal and data, it characterized in that to provide reliable wireless encryption communication between the transmission and reception.

In addition, a method for encrypting data having a frame structure and transmitting the same to a receiving side communication apparatus in the calling party communication apparatus includes: a first encryption step of first encrypting data having an HDLC frame structure; A frame structure forming step of forming a frame structure by adding a synchronization signal in front of an HDLC frame including primary encrypted data; A second encryption step of secondly encrypting both the synchronization signal and the data having the formed frame structure; A transmission step of transmitting to a receiving side communication apparatus by wireless communication; Characterized in that consists of.

In addition, the method for determining the error of the synchronization signal and data after receiving and decrypting the synchronization signal and data having an encrypted frame structure in the receiving-side communication device, the primary encryption signal and data secondary in the frame structure A first decoding step in which the frame structure includes a first decoded sync signal and data; A first error determining step of determining a first error based on the first decoded synchronization signal and a predetermined synchronization signal; A second decoding step of second decoding the first decoded data; A secondary error judging step of determining a secondary error by comparing a header value among the second decoded data with a header value obtained when a direct connection to a transmission-side communication device is performed in advance; Characterized in that consists of.

The present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram for making the first and second error determination of the reliable data determination method of the wireless encryption communication of the present invention, Figure 2 is a conceptual diagram for requesting the first error determination of the reliable data determination method of the wireless encryption communication of the present invention, 3 to 4 are conceptual diagrams for requesting the second error of the reliable data determination method of the present invention.

At this time, in each figure, the upper side is an order to proceed to the originating communication device, and the lower side is an order to proceed to the receiving communication device.

Specifically, the present invention provides an encrypted synchronization signal and data having a frame structure sent by the calling party communication device when wirelessly communicating with each other in a directly connected source and receiving device. After decrypting by the receiving side communication apparatus, it is possible to provide reliable wireless cryptographic communication between transmission and reception as the error of the synchronization signal and data is determined.

When the transmitter-side communication device and the receiver-side communication device are directly connected wirelessly, the synchronization signal and the data of the HDLC structure are stored in the receiver-side communication device, thereby determining an error thereafter.

In the frame structure, a synchronization signal is added before the data of the HDLC frame structure. In particular, the data of the HDLC structure includes header and frame data, and the header includes source data and destination data.

Meanwhile, the synchronization signal has a data space of 128 bits or more and 256 bits or less. When the synchronization signal is less than 128 bits, it is difficult to determine a degree of data error. When the synchronization signal exceeds 256 bits, the data is transmitted and the transmission speed is slowed.

A method of encrypting data having a frame structure and transmitting the same to a receiving side communication apparatus in the source communication apparatus includes: a first encryption step of first encrypting data having an HDLC frame structure; A frame structure forming step of forming a frame structure by adding a synchronization signal in front of an HDLC frame including primary encrypted data; A second encryption step of secondly encrypting both the synchronization signal and the data having the formed frame structure; A transmission step of transmitting to a receiving side communication apparatus by wireless communication; It is made of.

That is, before the synchronization signal and data of the frame structure are transmitted to the receiving side communication device, only the data of the HDLC frame is first encrypted in the primary encryption step, and the synchronization signal and data of the frame structure are totally 2 in the secondary encryption step. The car will be encrypted.

The method for determining an error of the synchronization signal and the data after receiving and decrypting the synchronization signal and the data having the encrypted frame structure in the receiving side communication apparatus includes: A first decoding step of decoding and including a primary decoded synchronization signal and data; A first error determining step of determining a first error based on the first decoded synchronization signal and a predetermined synchronization signal; A second decoding step of second decoding the first decoded data; A secondary error judging step of determining a secondary error by comparing a header value among the second decoded data with a header value obtained when a direct connection to a transmission-side communication device is performed in advance; It is made of.

The method of determining an error in the first error judging step is to compare a synchronization signal previously received and a currently received synchronization signal when a direct connection is made, and if a match ratio of more than a certain percentage (for example, 80%) does not occur, an error does not occur. On the contrary, if the match rate is lower than a certain percentage (eg, 80%), it is determined that an error has occurred.

In particular, in the first error judging step, for example, when the synchronization signal uses 128 bits of space in the first error judging step, and the predetermined predetermined percentage is 80%, a matching rate of 103 bits or more is determined. If it is seen, no error occurs. On the contrary, if the match rate is less than 103 bits, it is determined that an error has occurred.

In this case, when the receiving side communication apparatus determines the first error determination step error, the receiving side communication apparatus requests resynchronization from the transmitting side communication apparatus.

In the second error determination step, a method of determining an error is to compare the source and destination of the header included in the data previously received at the time of direct connection with the source and destination of the header included in the currently received data. Therefore, if the match rate is over a certain percentage (eg 80%), no error has occurred. On the contrary, if the match rate is less than a certain percentage (eg 80%), it is determined that an error has occurred.

At this time, in the second error determination step, the receiving side communication apparatus requests resynchronization from the transmitting side communication apparatus.

On the other hand, when an error occurs in the second error judging step, in the second error judging step, since the receiving side communication device passes the first error judging step and determines that the synchronization is normal, the error count is accumulated and accumulated. If the number of errors is less than a certain number (e.g. 3 times), the data of the data structure is used by the receiving communication device as it is.If more than a certain number of times (e.g. 3 times), the requesting device for resynchronization is requested. will be.

The predetermined percentage set in each of the first error judging step and the second error judging step is initially set and can be adjusted by an administrator.

Accordingly, the present invention provides a reliable data determination method of an encrypted synchronization signal having a frame structure sent by the calling party communication device when wirelessly communicating with each other directly in a wirelessly connected calling party and receiving party. After decoding the data at the receiving side communication apparatus, there is a remarkable effect of providing reliable wireless cryptographic communication between the transmission and reception by determining the error of the synchronization signal and the data.

Claims (3)

When the wireless communication device is directly connected to the wireless communication source and the receiving communication device, the encrypted synchronization signal and data having a frame structure sent by the calling communication device are decrypted by the receiving communication device, and then the synchronization signal is transmitted. And a reliable data determination method of wireless cryptographic communication, which provides reliable wireless encrypted communication between transmission and reception according to determining an error of data.
A method of encrypting data having a frame structure and transmitting the same to a receiving side communication apparatus in the source communication apparatus comprises: a first encryption step of first encrypting data having an HDLC frame structure; A frame structure forming step of forming a frame structure by adding a synchronization signal in front of an HDLC frame including primary encrypted data; A second encryption step of secondly encrypting both the synchronization signal and the data having the formed frame structure; A transmission step of transmitting to a receiving side communication apparatus by wireless communication; It consists of,
The method for determining an error of the synchronization signal and data after receiving and decrypting the synchronization signal and data having an encrypted frame structure in the receiving side communication apparatus comprises: firstly decoding the second encryption signal and data in the frame structure. The primary frame decoding step includes a primary decoded synchronization signal and data; A first error determining step of determining a first error based on the first decoded synchronization signal and a predetermined synchronization signal; A second decoding step of second decoding the first decoded data; A secondary error judging step of determining a secondary error by comparing a header value among the second decoded data with a header value obtained when a direct connection to a transmission-side communication device is performed in advance; Reliable data determination method of wireless encryption communication, characterized in that consisting of delete delete

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