RU2546307C1 - Information hiding device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: information hiding device comprises: a signal attenuation unit, two key memory units, a masking signal shaping unit, a subtracting unit, six adder units, four multiplier units, an information transfer device unit, a factor shaping unit, a divider unit.

EFFECT: improvement of security and accuracy of recovery of the secured signal.

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Description

The invention relates to telecommunications and computer technology, to the field of methods and devices for steganographic data conversion, and can be used in communication, computing and information systems for steganographic information hiding during data exchange by government, law enforcement, defense, banking and industrial institutions, when there is a need for storage and transmitting confidential information.

As an analogue of the invention, the known radio masking device [1] can be considered, which comprises a noise generator consisting of a system of two coupled generators, a capacitive coupling element between them, a radiating antenna and a low-frequency noise source. The first generator contains a non-linear amplifier, a delay line and an inertial circuit of auto-bias. The output of the nonlinear amplifier is connected to the input through the delay line, the inertial autoset circuit is connected between the common electrode of the active element of the nonlinear generator and the common bus. The second generator contains a non-linear amplifier and an adjustable delay line. The output of the non-linear amplifier is connected to the input through an adjustable delay line. The delay line allows you to adjust the position of the natural frequencies of this generator. The output of the first generator is connected to the input of the second generator using a capacitive coupling element. An element of the oscillatory system is a magnetic dipole emitting antenna. The input of the first generator is connected to the output of the low-frequency noise source.

A disadvantage of the known device is the generation of noise by the receiving side, which limits the coverage area of the radio mask, as well as the use of the principle of additive overlay, which reduces its resistance to attacks.

A device is known [2, Fig. 7.1] (prototype) hiding information in audio signals containing an encoder and a decoder. The encoder contains a functional converter, the encoder input is connected to the first input, and the random number generator output is connected to the second input, an adder, the encoder input is connected to the first input, the output of the functional converter is connected to the second input, and the output is connected to the encoder output. The input of the decoder is connected to the first input of the functional converter and to the second input of the first multiplier, the output of the random number generator is connected to the first input of the first multiplier, to the second input of the functional converter and to the second input of the second multiplier, the output of the functional converter is connected to the first input of the second multiplier, the output of the first the multiplier is connected to the statistics analysis unit, the output of which is connected to the first input of the threshold device, the output of the second multiplier is connected to the second the threshold device, the output of the threshold device is the output of the device.

The disadvantage of the prototype is the inability to recover hidden information in full, since the result of the device is the decision on the availability of hidden information.

The purpose of the invention is to increase the secrecy and accuracy of information recovery.

To this end, a signal attenuation unit is connected to the input of the device, the output of the signal attenuation unit is connected to the first input of the subtraction unit, to the first the input of the first summing block and to the first input of the second summing block, the first output of the first key memory block is connected to the second input of the first summing block, the second output is connected to the first input of the third block totalization, the third output is connected to the second input of the subtraction unit, the output of the masking signal generating unit is connected to the second input of the first multiplication unit and to the second input of the second multiplication unit, the output of the subtraction unit is connected to the second input of the third summing unit and to the second input of the fourth summing unit, output the first summation block is connected to the first input of the first multiplication block, the output of the third summation block is connected to the first input of the second multiplication block, the output of the first multiplication block connected to the second input of the second summing unit, the output of the second multiplication unit is connected to the first input of the fourth summing unit, the output of the second summing unit is connected to the first input of the information transfer unit, the output of the fourth summing unit is connected to the second input of the information transfer unit, the first output of the information transfer unit is connected to the first input of the third multiplication unit and to the first input of the fifth summing unit, the second output of the information transfer unit is connected to the first input of the fourth smart unit To the second input of the fifth summing block, the first output of the second key memory block is connected to the first input of the coefficient forming block, the second output is connected to the second input of the coefficient forming block, the third output is connected to the third input of the coefficient forming block, the first output of the coefficient forming block the second input of the third multiplication unit, the second output is connected to the second input of the fourth multiplication unit, the third output is connected to the third input of the sixth summing unit, even the fourth output is connected to the third input of the fifth summing block, the output of the third multiplication block is connected to the first input of the sixth summing block, the output of the fourth multiplication block is connected to the second input of the sixth summing block, the output of the sixth summing block is connected to the first input of the division block, the output of the fifth summing block is connected to the second input of the division block, the output of the division block is the output of the device.

The technical results that will be obtained by using the invention are an information hiding device that allows masking a useful signal in an arbitrary noise signal with a signal-to-noise ratio of less than 0.1 and restoring the hidden information in full by the receiving side.

In FIG. 1 shows a block diagram of an information hiding device. The device comprises a signal attenuation unit 1, first and second keys memory blocks 2 and 12, a masking signal generating unit 3, a subtraction unit 4, six summing blocks 5, 9, 6, 10, 17 and 16, respectively, four multiplication blocks 7, 8, respectively , 14 and 15, the unit of the information transmission device 11, the unit for generating the coefficients 13, the division unit 18.

In FIG. Figure 2 shows the time dependences of the two signals y ₁ (n) and y ₂ (n), and the masking signal z (n).

In FIG. Figure 3 shows the spectrum of the signal to be hidden.

In FIG. 4 shows the spectrum of the signal at the output of the summing unit 9.

In FIG. 5 shows the spectrum of the signal at the output of the summing unit 10.

In FIG. 6 shows a histogram of the probability density distribution of a masking signal.

In FIG. 7 shows a histogram of the probability density distribution of the signal at the output of the summing unit 9.

In FIG. 6 shows a histogram of the probability density distribution of the signal at the output of the summing unit 10.

The device operates as follows.

The signal to be hidden is fed to signal attenuation unit 2, where the first signal y _{1 is formed} :

where y (n) is the samples of the signal to be hidden.

The second signal is generated in block 4 using the first signal:

where K ₁ is the value of the first key stored in the key memory block 3.

The value of the first key is a checksum that connects signals (1) and (2) [3]. Block 1 generates a random signal, which is necessary to mask the received two signals.

The general view of the steganographic transformation is described by the following expressions:

where z are the samples of the masking signal;

y - samples of hidden data;

φ is the steganographic transformation function.

The device implements a linear model of steganographic transformation. The steganographic conversion function has the following form:

where K ₂ and K ₃ are the keys to the steganographic transformation.

The samples of the signals that are fed to the inputs of the information transfer device 11 are described as follows:

The system of equations (5) is a mathematical model of the encoder. In both equations (5), the same samples of the masking signal are used. Two signals are transmitted using known information transmission devices, for example, stereo audio signal transmission devices, quadrature amplitude modulated signal and other devices.

The ratio of the values of the embedded data to the values of the masking signals can be much less than unity, as shown in FIG. 2. The received signals (5) are filled stegocontainer. A distinctive feature of the container formed in accordance with (5) is the presence of two signals that have a common masking component in their composition. This feature allows the use of functional compressive displays [3] for opening the container.

Consider the effectiveness of masking a hidden signal. We take harmonic oscillation as a hidden signal, and a random signal with a uniform probability density distribution as a masking signal. We will form the first and second signals. The signals are shown in FIG. 2.

Let us compare the spectra of the hidden signal (Fig. 3) and the signals after the steganographic transformation (Figs. 4 and 5). It is seen that the harmonic of the hidden signal in the spectra of the signal of the container is not allocated.

Let us compare the probability density of the masking signal and the signals after the steganographic transformation. In FIG. 6 shows the probability density of a masking signal. The probability density distributions of the container signals are shown in FIG. 7 and FIG. 8. It is seen that after embedding the hidden signal in the container, the band occupied by the histograms of the container signals does not increase.

The signals after conversion fall into the block of information transfer 11. This block implies a system of information transfer, which includes signal conversion devices, transmitting and receiving devices, and an information transmission line. As an example of an information transmission system that implements the simultaneous transmission of two signals on the same communication channel, we can consider a system using quadrature amplitude modulation of the signal [4] with subsequent demodulation.

Extraction of the hidden signal is performed using the inverse steganographic transformation. To extract the hidden signal by the receiving party, you need to know the values of the keys K ₁ , K ₂ and K ₃ .

The extraction of hidden information from the container (5) is performed using compression transformations. The recovery of two signals (1) and (2) from the container is performed using the following expressions [3]:

Then the hidden signal is restored:

Combining expressions (6) and (7) we obtain:

where the coefficients k are formed in block 13 according to the values of the keys K as follows:

k ₁ = 2 (K ₁ + K ₃ ); k ₂ = 2K ₂ ; k ₃ = 2K ₁ K ₂ ;

Expression (8) is a mathematical model of the decoder and is implemented using blocks 14-18 (Fig. 1).

The output signal of the decoder, in the absence of interference in block 11 and quantization errors during the calculation, corresponds to the hidden signal with absolute accuracy.

Thus, the proposed device allows you to effectively mask the hidden signal in an arbitrary noise signal and transmit it over the communication line with subsequent restoration.

 Information sources

1. Patent for the invention No. 2170493. Russian Federation, IPC N04K. Radio masking device / V.A. Bezrukov, V.P. Ivanov, B.C. Kalashnikov, M.N. Lebedev // (Russia); declared 05/15/2000; publ. 05/15/2001.

2. Gribunin V.G. Digital steganography / V.G. Gribunin, I.N. Okov, I.V. Turintsev. - M .: Solon-Press. 2002 .-- 272 p.

3. Shakursky, V.K. Algorithm for correction of multifactor additional error of measuring transducers / V.K. Shakursky // Devices and control systems. - 1996. - No. 7. - S. 20-23.

4. Sergienko, A.B. Digital signal processing / A.B. Sergienko //. - St. Petersburg: Peter, 2005 .-- 604 p.

Claims (1)

An information hiding device containing a masking signal generating unit, first and second key memory blocks and an information transmission unit, characterized in that, in order to increase the stealth and accuracy of recovering the hidden signal, a signal attenuation unit is introduced into the device, to the input of which the device input is connected, the output of the signal attenuation unit is connected to the first input of the subtraction unit, to the first input of the first summing unit and to the first input of the second summing unit, the first output of the first key memory block connected to the second input of the first summing block, the second output is connected to the first input of the third summing block, the third output is connected to the second input of the subtraction block, the output of the masking signal generating block is connected to the second input of the first multiplication block and to the second input of the second multiplication block, the output of the subtraction block connected to the second input of the third summing unit and to the second input of the fourth summing unit, the output of the first summing unit is connected to the first input of the first multiplying unit, output t this summation block is connected to the first input of the second multiplication block, the output of the first multiplication block is connected to the second input of the second summation block, the output of the second multiplication block is connected to the first input of the fourth summation block, the output of the second summation block is connected to the first input of the information transmission block, the output of the fourth block summation is connected to the second input of the information transfer unit, the first output of the information transfer unit is connected to the first input of the third multiplication unit and to the first input of the fifth of the first summing block, the second output of the information transmission block is connected to the first input of the fourth multiplication block and to the second input of the fifth summing block, the first output of the second key memory block is connected to the first input of the coefficient forming block, the second output is connected to the second input of the coefficient forming block, third output connected to the third input of the coefficient forming unit, the first output of the coefficient forming unit is connected to the second input of the third multiplication unit, the second output is connected to w the fourth input of the fourth multiplication block, the third output is connected to the third input of the sixth summing block, the fourth output is connected to the third input of the fifth summing block, the output of the third multiplication block is connected to the first input of the sixth summing block, the output of the fourth multiplication block is connected to the second input of the sixth summing block, the output of the sixth summing block is connected to the first input of the division block, the output of the fifth summing block is connected to the second input of the division block, the output of the division block is the output of royals.

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