KR19980054695A - Eavesdropping device for digital cell phones. - Google Patents

Abstract

The present invention relates to an apparatus for preventing eavesdropping of a digital cellular phone, wherein the digital cellular phone is set so that another person cannot make eavesdropping during a telephone call between users of the digital cellular phone.

In the conventional encryption system, when the ESN of the subscriber's mobile phone (MS) is known or when the ESN is detected when the information is exchanged with the base station (BS) before starting a call, and the information is obtained by accessing the base station (BS). In the case of reading, eavesdropping becomes possible, which causes problems such as invasion of personal privacy or loss of important information.

Accordingly, in the present invention, in order to solve the problems described above, a long code code can be generated by inputting a user defined long code code mask between each mobile phone (MS to MS). The system is configured so that the base station (BS) also processes the data in the encrypted state, thereby enabling the promised non-call between users.

Description

Eavesdropping device for digital cell phones.

The present invention relates to an apparatus for preventing eavesdropping of a digital cellular phone, wherein the digital cellular phone is set so that another person cannot make eavesdropping during a telephone call between users of the digital cellular phone.

Referring to FIG. 1, the encryption scheme of a conventional digital cellular phone is as follows.

When a voice is input into the microphone 1 of the subscriber's mobile station (MS), the voice signal input from the voice encoder 2 is coded.

The channel coding unit 3 performs channel coding for a call with the other party on the voice signal encoded in this way.

The channel coded signal is inputted to a modulator 6 through an long code code generated by a long code generator (LCG) 4 and an exclusive OR 5. It is modulated and sent to the base station (BS).

At this time, the long code code generator 4 generates a long code code by inputting a long code mask (LCM) as shown in FIG.

Thereafter, the base station BS demodulates the modulated signal through the demodulator 7 in the reverse order as described above, and the demodulated signal includes the long code code generated by the long code code generator 8. The exclusive logic sum 9 is taken and transmitted to the digital cellular network (DCN) through the channel decoding unit 10 and the voice decoder 11.

In order to start a call, the mobile phone (MS) sends and receives various information before starting a call by opening a call channel, and the mobile phone (MS) transmits information of an ESN (Electrical Serial Number) to the base station (BS). bar,

In the mobile phone MS, as described above, a long code code is generated using a long code code mask (LCM) made with an ESN to store voice data to the base station BS, and the base station BS starts a call. The long code code mask (LCM) can be made using the ESN received from the mobile phone MS.

Thus, the long signal code is generated through the long code code generator 8 of the base station BS using the long code code LCM generated by using the ESN information from the mobile phone MS. Can be recovered [(A XOR B) XOR B = A].

FIG. 3 is a diagram showing an embodiment of the long code code generator 8. As shown in FIG.

However, in such a conventional encryption scheme, when the ESN of the subscriber's cellular phone (MS) is known or when the ESN is known when the information is exchanged with the base station (BS) before starting a call, the access is connected to the base station (BS). In the case of reading the information by using the eavesdropping is possible, the problem of personal privacy invasion or loss of important information occurs.

Accordingly, in the present invention, in order to solve the problems described above, a long code code can be generated by inputting a user defined long code code mask between each mobile phone (MS to MS). The system is configured to enable promised non-call between users, so that external eavesdropping is impossible.

1 is a block diagram showing a system configuration of an encryption method of a conventional digital cellular phone.

Fig. 2 is a diagram showing a data structure of a long code code mask in the related art.

Fig. 3 is a diagram showing a configuration example of a long code long code code generation unit in the related art.

Fig. 4 is a block diagram showing the construction of a wiretap prevention apparatus of a digital mobile telephone according to the present invention.

The configuration of the present invention is an encryption device for a digital cellular phone,

Speech encoding means for encoding a speech signal input from a microphone, first speech code generating means for generating a first speech code using a user-defined speech code mask, and the encoded speech signal and the first speech code A first mixing means for synthesizing and encoding a code code signal, a channel coding means for channel coding the output of the encrypted first mixing means, and a second long code code for generating a second long code code using an ESN. Second long code code generating means for generating, second mixing means for synthesizing and encrypting the channel coded signal and the second long code code signal, and transmitting for transmitting the voice signal encrypted by the second mixing means. It comprises a means.

The first mixing means and the second mixing means are characterized by consisting of exclusive logical combining means for inputting a long code code.

Referring to FIG. 4, which shows an embodiment of the wiretap prevention apparatus of the present invention digital cellular phone, which is constituted as described above, its configuration and operation will be described in detail as follows.

In the communication flow diagram using the digital mobile communication network DCN through the base stations BS1 and BS2 of the mobile phone MS1 and the mobile phone MS2,

User-defined to generate a user-defined long code code by using the voice encoder 12 for encoding the voice signal of the user input to the microphone 11 and a user-defined long code code mask (UD LCM). A long code generator 13, an exclusive logical sum 14 for inputting a user-defined long code to an encoded voice signal, a channel coding unit 15 for channel coding a user-defined encrypted voice signal, and A long code code generator 16 for generating a long code code using the long code code mask LCM1, an exclusive logical sum 17 for inputting a long code code to the channel coded speech signal, and encryption in this manner. As a modulator 18 for transmitting the voice signal, a transmission related component of the mobile phone MS1 is configured.

The base station BS1 of the mobile terminal MS1 uses a demodulator 19 for demodulating the voice signal modulated by the modulator 18 and the ESN received from the mobile phone MS1. A long code code generator 20 for generating a long code code by using a long code code mask LCM1 generated by the first code code, and a speech signal and a long code code generator 20 demodulated from the demodulator 19; Exclusive logical sum 21, which takes in the long code code generated by the input signal, and the audio signal recovered from the original logical sum 21 from the original signal by channel decoding, and receives the base station BS2 through the digital mobile telephone network (DCN). Channel decoding unit 22 for transmitting to the side,

The receiving base station BS2 is a channel coder 23 for channel coding the voice signal transmitted through the digital mobile telephone network DCN to the mobile phone MS2, and a long code code for generating a long code code. The receiver 24 modulates a predetermined encrypted voice signal through the exclusive logical sum 25 which receives the generated long code code and the channel coded voice signal, and the exclusive logical sum 25 to receive the mobile phone MS2. It consists of a modulator 26 for transmitting to

A demodulator 26 for demodulating a voice signal received through a digital mobile communication network (DCN) from the above-described technical configuration, a long code code generator 27 for generating a long code code, and a generated long code An exclusive OR 28 for inputting the code and the demodulated voice signal, a channel decoder 29 for channel decoding the output voice signal of the exclusive OR 28, and a user-defined long code code mask (UD LCM). A user defined long code code generator 30 for generating a user defined long code code, an exclusive logical sum 31 for inputting the generated user defined long code code and a channel decoded signal, and an exclusive logical sum 31 The reception related sub-configuration of the mobile phone MS2 is made as a voice decoder 32 for voice decoding to output a user-decrypted voice signal to the speaker 33 through a voice signal.

The present invention, which is configured as such, enables users to encrypt and release their own voice signals transmitted and received between both mobile phones MS1 and MS2 using user-defined long code codes, thereby preventing others from eavesdropping. ,

The long code code mask LCM1 used for encryption is used for the transmission related link from the mobile phone MS1 to the base station BS1, and the long code code mask LCM2 is used for the mobile phone from the base station BS2. It is used for encryption on reception-related links to (MS2).

First, the voice is encoded with respect to the voice signal input to the microphone 11, and the hatched voice signal A1 is the long code code and the exclusive logical sum 14 generated through the user-defined long code code generator 13. As an input of), an exclusive OR 14 of these two signals is taken and encrypted with the user's desired password.

At this time, the long code code generator 13 generates the long code code by using the user defined long code code mask LCM1.

The user-encrypted signal as described above is a cryptographic system for the call with the mobile terminal MS2 to be received.

As described above, the signal B1 encrypted through the exclusive OR 14 is coded through the channel coding unit 15, and the coded signal C1 is generated from the long code code generator 16. The exclusive logical sum 17 is taken together with the long code code to perform encryption with the base station BS1.

The encrypted signal D1 is transmitted to the base station BS1 through the modulator 18, and the transmitted signal is demodulated through the demodulator 19 configured in the base station BS1 to form a long code code generator 20. Along with the long code code generated from), the original signal is restored through an exclusive OR 21.

Subsequently, the signal is decoded by the channel decoding unit 22 and transmitted to the receiving base station BS2 through the digital mobile communication network DCN, and the transmitted signal is encrypted in the reverse order from the base station BS1 and modulated ( 26) to the mobile phone MS2.

The mobile phone MS2 receives the same signal as described above and outputs the demodulated signal D2 through the demodulator 26, and the demodulated signal D2 is generated by the long code code generator 27. It is inputted to the exclusive logical sum 38 together with the long code code to release the encryption with the base station BS2.

After that, the channel decoding is performed, and the long code code generated by the user defined long code code generator 30 using the user defined long code code mask (UD LCM) and the signal B2 subjected to the channel decoding are exclusive logical sums. The password 31 is entered to cancel the password set between the mobile phones MS1 and MS2.

The signal A2 released as described above is output to the speaker 33 via the voice decoder 32.

At this time, in the digital mobile communication network between the mobile phones MS1 and MS2 and the base stations BS1 and BS2 or the base station and the base station, if the data does not change due to padding or noise, The signal has a relationship such as B1 = B1 '= B2' = B2, C1 = C1 '= C2' = C2, D1 = D1 '= D2' = D2.

Also, if the user defined long sign code mask (UD LCM) matches, then A1 = A2.

Here, if the user-defined long code code masks of the transmitting side mobile phone MS1 and the receiving side mobile phone MS2 are different from each other by one bit, A1 and A2 have a completely different appearance, and in this case, the mobile phone MS1 The information sent is not readable.

For example, if the size of a user-defined long code code mask is set to 20 bits, the number of cases is 2 ²⁰ to 1,048,576.

In such a mobile phone, an encrypted call between mobile phones having the same user-defined long code code mask is enabled, and the communication can be performed in the following order.

You make a call without encryption, and you will be asked if you want to make a non-call.

After confirming that both parties know the same encryption code, both mobile phones start to communicate with each other.

As described above, the mobile phone of the present invention sets up the same passwords between the mobile phones so that information can be determined according to the passwords set between the mobile phones.

As described above, since the mobile phone processes the data in the encrypted state by encrypting using a user-defined long code code mask when coding a channel in a mobile phone, eavesdropping is fundamentally impossible, and both parties use the same encryption code. You can only make calls if you know them, so you can be assured of a complete secret call.

Claims (2)

Speech encoding means for encoding a speech signal input from a microphone, first speech code generating means for generating a first speech code using a user-defined speech code mask, and the encoded speech signal and the first speech code A first mixing means for synthesizing and encoding a code code signal, a channel coding means for channel coding the output of the encrypted first mixing means, and a second long code code for generating a second long code code using an ESN. Second long code code generating means for generating, second mixing means for synthesizing and encrypting the channel coded signal and the second long code code signal, and transmitting for transmitting the voice signal encrypted by the second mixing means. And a means for preventing eavesdropping in a digital cellular phone. 2. The apparatus of claim 1, wherein the first mixing means and the second mixing means comprise exclusive logical matching means for inputting a long code code.