RU62469U1 - ADAPTIVE WAVELET CONVERSION CALCULATION DEVICE - Google Patents

Abstract

The utility model relates to computer technology and can be used as a block in devices for processing signals of various nature. The proposed utility model allows the calculation of the wavelet transform of a signal adaptive to the characteristics of the signal using the signal scaling factor calculated on the basis of the spectral characteristics of the signal. The problem is solved due to the fact that the Fourier transform is calculated for the original signal, the signal power spectrum is calculated, and the cutoff frequency, which is the signal scaling factor, is calculated on the basis of the given cutoff power when separating the low-frequency and high-frequency components of the original signal. The obtained coefficient value is used when performing the wavelet transform of the signal.

Description

The utility model relates to computer technology and can be used to process signals of various nature.

A known method and device for the quick calculation of a discrete wavelet - signal conversion with an arbitrary step of discretization of scale factors (patent of the Russian Federation No. 2246132, CL G06F 17/14, 2005, Bull. No. 4), the method is based on the representation of the analyzed signal and the original mother wavelet in spectral plane with subsequent logarithmic scaling, the device contains an analog-to-digital converter, two computers for fast Fourier transform, two read-only memory devices, a complex unit conjugations, M multipliers, M inverse Fourier transform calculators. The disadvantage of this device is hardware redundancy and the inability to adaptively change the sampling step of the scale factors.

There is a method of calculating a series-parallel wavelet transform (patent of the Russian Federation No. 2249850, class G06F 17/14, 2004, Bull. No. 10), which consists in the fact that with direct wavelet transform the input information in the form of multiple samples is processed in sequential iterations, in each of which the input information is passed through low-pass and high-pass filters. Thinned through one report from a low-pass filter are inputs of the next iteration, and thinned through one count from a low-pass filter of the last iteration and from a high-pass filter are wavelet transform coefficients. With the reverse wavelet transform

input information are direct wavelet transform coefficients supplemented with zeros through a given number of bits. This information is passed through a set of filters, the structure of which is uniquely determined by the low-frequency and high-frequency filters of the direct wavelet transform, and the output information is determined from the readings from these filters. The disadvantage of this device is the inability to adaptively change the sampling step of the scale factors.

The technical task of the utility model is to calculate the wavelet transform, adaptive to the signal.

The technical problem is solved by the formation and use of an adaptive scale factor.

The adaptive choice of the scale factor is based on the fact that when moving to each subsequent signal viewing scale, the accuracy of its shape reproduction is sharply reduced. The reason for this is that the energy of the signals (at least in many specific applications), as a rule, increases with the transition to lower frequencies. With a large-scale analysis, a sharp cut-off of part of the frequency components that carry significant information is possible. It is during such a “jump” from the scale k to 2 · k that the loss of the defining feature can occur.

The proposed approach is to adaptively reduce the magnification of the change in the scale of consideration as the coefficient k increases. In this case, finer tracking of the behavior of the signal features of interest is achieved.

Initially, the signal power P _{s is} calculated, which is no less than the one closest to the cut-off power P from above (i.e., P _s exceeds P by the minimum number: P _s ≥ P):

where A _i is the i-th component of the energy spectrum of the signal,

s _max - the number of components of the energy spectrum of the signal.

Thus, the scale factor selected as the cutoff frequency when separating the LF and HF components is finally calculated as follows:

where K is the scale factor (cutoff frequency when separating the LF and HF components),

P is the signal power to be cut off,

P _s - signal power, which corresponds to the closest to the cut-off power P,

s is the number of summed spectral components corresponding to power P _s .

Zooming a whole number of times is achieved as a result of three operations:

1. Using a filter with a given bandwidth for each row (column).

2. Interpolation of the signal, increasing the number of samples by N times (N is an integer).

3. Decimation of the signal, reducing the number of samples by M times (M is an integer).

If the coefficient of scale change K is less than 0.01 (K <0.01), then N = K · 10000, M = 10000 are selected; if the magnitude of the scale change factor K is greater than or equal to 0.01 and less than or equal to 0.1 (0.01≤K≤0.1), then N = K · 1000, M = 1000 are selected; if the value

the coefficient of change of scale K is greater than 10 (K> 0.1), then N = K · 100, M = 100 are selected.

Thus, the use of this approach will allow for more subtle signal analysis.

A block diagram of a device for calculating an adaptive wavelet transform that implements the above approach is shown in Fig. 1, Fig. 2 shows a block diagram of a block for calculating signal processing parameters (block 7), Fig. 3 shows a block diagram of a block for calculating signal interpolation / decimation coefficients ( block 7.11), Fig. 4 shows a block diagram of a signal interpolation / decimation block (block 8).

The adaptive wavelet transform calculation device comprises an analog-to-digital converter (block 1), a key (block 2), read-only memory 1 (block 3), read-only memory 2 (block 4), convolution (execution) block 1 (block 5) , convolution block (execution) 2 (block 6), signal processing parameter calculation block (block 7), signal interpolation / decimation block (block 8), addition device 1 (block 9), comparison device 1 (block 10), block control and generation of addresses (block 11), and the input of analog-to-digital convert When firing (block 1), the analyzed signal is supplied, the output of the analog-to-digital converter (block 1) is connected to the first input of the key (block 2), the output of the key is connected to the first input of convolution block 1 (block 5), with the first input of convolution block 2 (block 6), with the second input of the signal processing parameter calculation unit (block 7), the output of the read-only memory 1 (block 3) is connected to the second input of the convolution unit 1 (block 5), the output of the read-only memory 2 (block 4) is connected to the second input convolution block 2 (block 6), the output of convolution block 1 (block 5) is the lane the output of the device, the output of convolution unit 2 (block 6) is connected to the third input of the signal interpolation / decimation block (block 8), to the first

the input of the signal processing parameter calculation block (block 7) is supplied with the signal cut-off value, the first output of the signal processing parameter calculation block (block 7) is connected to the first input of the comparison device 1 (block 10), the second output of the signal processing parameter calculation block (block 7) connected to the first input of the signal interpolation / decimation block (block 8), the third output of the signal processing parameter calculation block (block 7) is connected to the second input of the signal interpolation / decimation block (block 8), the first output of the interpolation / dec block signal mimics (block 8) is connected to the first input of addition device 1 (block 9), the second output of the signal interpolation / decimation block (block 8) is connected to the second key input (block 2) and is the second output of the adaptive wavelet transform calculation device, output addition device 1 (block 9) is connected to the second input of the comparison device 1 (block 10), the output of the comparison device 1 (block 10) is connected to the control and address generation unit (block 11), and the control and generation of addresses (block 11) is connected with all of the above blocks .

The signal processing parameter calculation unit (block 7) contains a fast one-dimensional Fourier transform calculation device (block 7.1), an addition device 2 (block 7.2), an addition device 3 (block 7.3), a division device 1 (block 7.4), a multiplication device 1 (block 7.5), a comparison device 2 (block 7.6), a division device 2 (block 7.7), an addition device 4 (block 7.8), a block for calculating interpolation / decimation coefficients (block 7.9), a division device 3 (block 7.10), a multiplier 2 ( block 7.11), and at the input of the device for calculating fast conversion I Fourier (block 7.1) a signal is output from the key output (block 2), the output of the fast Fourier transform calculation device (block 7.1) is connected to the first input of addition device 2 (block 7.2) and the third input of addition device 3 (block 3),

the output of addition device 2 (block 2) is connected to the first input of division device 1 (block 7.4), the first output of addition device 3 (block 7.3) is connected to the second input of division device 1 (block 7.4), the second output of addition device 3 (block 7.3) connected to the third input of the multiplier 1 (block 7.5), the output of the divider 1 (block 7.4) is connected to the second input of the comparison device 2 (block 7.6) and to the first input of the divider 2 (block 7.7), the output of the multiplier 1 (block 7.5 ) connected to the second input of the division device 2 (block 7.7), the output of the device equation 2 (block 7.6) is connected to the first input of the multiplier 1 (block 7.5) and to the first input of the addition device 4 (block 7.8), the output of the addition 4 (block 7.8) is connected to the first input of the multiplier 2 (block 7.11), output division device 2 (block 7.7) is connected to the first input of the signal interpolation / decimation coefficient calculation block (block 7.9), the first output of the signal interpolation / decimation coefficient calculation block (block 7.9) is the second output of the signal processing parameter calculation block (block 2), the second block output calculated the signal interpolation / decimation coefficient (block 7.9) is the third output of the signal processing parameter calculation block (block 2), a constant value is supplied to the first input of the division device 3 (block 7.10) (the value of the constant supplied to the device input is 100), and to the second the input of the division device 3 (block 7.10) is the value of the cutoff power of the signal, the output of the division 3 (block 7.10) is the first output of the block for calculating the signal processing parameters (block 7), the quantity on the cut-off signal power, the output of the multiplier 2 is connected to the second input of the multiplier 1 (block 7.5) and to the first input of the comparison device 2 (block 7.6).

The block for calculating the interpolation / decimation coefficients (block 7.9) includes a comparison device 3 (block 7.9.1), a comparison device 4 (block 7.9.2), a comparison device 5 (block 7.9.3), a comparison device 6 (block 7.9. 4), a multiplier 3 (block 7.9.5), a multiplier 4 (block 7.9.6), a multiplier 5 (block 7.9.7), a multiplier 6 (block 7.9.8), a multiplier 7 (block 7.9. 9), a multiplication device 8 (block 7.9.10), an addition device 5 (block 7.9.11), an addition device 6 (block 7.9.12), and the first input of the comparison device 3 (block 7.9.1) a constant value appears (the value of the constant supplied to the input of the device is 0.1), the second input of the comparison device 3 (block 7.9.1) receives the value from the output of the division device 2 (block 7.7), the output of the comparison device 3 (block 7.9.1) is connected with the second input of the multiplying device 3 (block 7.9.5), a constant value (the value of the constant supplied to the input of the device is 0.01) is supplied to the first input of the comparing device 4 (block 7.9.2), the second input of the comparing device 4 (block 7.9.2 ) connected to the output of the division device 2 (block 7.7), the output of the device and comparison 4 (block 7.9.2) is connected to the third input of the multiplying device 3 (block 7.9.5), a constant value is supplied to the first input of the comparison device 5 (block 7.9.3) (the value of the constant supplied to the input of the device is 0.1), the second input of the comparison device 5 (block 7.9.3) is connected to the output of the division device 2 (block 7.7), the output of the comparison device 5 (block 7.9.3) is connected to the second input of the multiplier 4 (block 7.9.6), to the first input of the device comparison 6 (block 7.9.4) receives a constant value (the value of the constant supplied to the input of the device va is equal to 0.01), the second input of the comparison device 6 (block 7.9.4) is connected to the output of the division device 2 (block 7.7), the output of the comparison device 6 (block 7.9.4) is connected to the second input of the multiplier 5 (block 7.9.7) , at the first input of the multiplying device 3 (block 7.9.5) a constant value is received (the value of the constant supplied to the input of the device is 1000),

the output of the multiplier 3 (block 7.9.5) is connected to the first input of the multiplier 6 (block 7.9.8) and to the first input of the addition 6 (block 7.9.12), the first input of the multiplier 4 (block 7.9.6) constant value (the value of the constant supplied to the input of the device is 100), the output of the multiplier 4 (block 7.9.6) is connected to the first input of the multiplier 7 (block 7.9.9) and to the second input of the addition device 6 (block 7.9.12) , at the first input of the multiplying device 5 (block 7.9.7), a constant value (constant value the current supplied to the input of the device is 10000), the output of the multiplier 5 (block 7.9.7) is connected to the first input of the multiplier 8 (block 7.9.10) and to the third input of the addition device 6 (block 7.9.12), to the second input multiplying device 6 (block 7.9.8) receives the value from the output of division device 2 (block 7.7), the output of multiplying device 6 (block 7.9.8) is connected to the first input of addition device 5 (block 7.9.11), to the second input of the multiplying device 7 (block 7.9.9) receives the value from the output of the division device 2 (block 7.7), the output of the multiplication device 7 (block 7.9.9) is connected to the second input of the addition device 5 (block 7.9.11), the second output of the multiplier 8 (block 7.9.10) receives the value from the output of the division device 2 (block 7.7), the output of the multiplier 8 (block 7.9.10) is connected to the third input of the addition device 5 (block 7.9.11), the output of the addition device 5 (block 7.9.11) is the first output of the adaptive wavelet transform calculation device, the output of the addition device 6 (block 7.9.12) is the second the output of the adaptive wavelet transform computation device.

The block for performing interpolation / decimation of the signal (block 8) contains an interpolation device (block 8.1) and a decimation device (block 8.2), and the signal from the output of convolution device 2 (block 6) is supplied to the first input of the interpolation device (block 8.1), and to the second input devices

the interpolation coefficient of the signal is interpolated from the third output of the signal processing parameter calculation unit (block 7), the output of the interpolation device is connected to the second input of the decimation device (block 8.1), the decimation coefficient of the signal from the second output of the calculation block is fed to the first input of the decimation device (block 8.2) signal processing parameters (block 7), the first output of the decimation device (block 8.2) is connected to the second input of the comparison device 1 (block 10), the second output of the decimation device is the output of the subtraction device Lenia adaptive wavelet - transform.

The adaptive wavelet transform computation device operates as follows.

According to the general initialization signal, zero values are supplied to the inputs of all devices and the internal registers of addition devices are reset.

The signal download signal to the input of the analog-to-digital Converter (block 1) receives the analyzed signal s (t). After its conversion to digital form, the analog-to-digital converter (block 1) sends a data ready signal to the control and address generation block (block 11). Upon receipt of the data readiness signal from the analog-to-digital converter (block 1), the control and address generation unit (block 11) sends a data output signal to the analog-to-digital converter to the first key input (block 2), after receiving the data to the analog-to-digital converter (block 1) sends a discrete sample s [n] to the first key input (block 2). The control and address generation unit analyzes the key state (block 2), if the key (block 2) is in state 0, then a digital sequence is sent to the key output (block 2) from the first key input (block 2), otherwise - from the second input. After issuing a synchronizing signal to download data to the key (block 2), from its output a discrete signal is fed to the first inputs of the blocks

performing convolution (block 5 and block 6) and to the second input, a block for calculating the signal processing parameters (block 7).

Then, to the read-only memory 1 (block 3) and read-only memory 2 (block 4), a synchronization data signal is received, after which the high-frequency samples (to block 5 from block 5) are received at the second inputs of the convolution blocks (block 5 and block 6) 3) and low-pass (on block 6 from block 4) filters. After receipt of the convolution execution blocks (blocks 5 and 6) of synchronization convolution signals, they carry out the convolution of discrete signals located at the first inputs with filters supplied to the second inputs. The result of the operation of convolution unit 1 (block 5) is sent to the output of the adaptive wavelet transform calculation device as the high-frequency component of the signal, the result of the operation of convolution unit 2 (block 6) is sent to the third input of the signal interpolation / decimation block (block 8). Upon receipt of a synchronizing signal for loading data to the signal processing parameters calculation unit (block 7), the cut-off power value is loaded to the device at the first input, and the discrete signal under analysis is loaded to the second input.

After the synchronization signal of the calculation is received on the signal processing parameters calculation unit (block 7), the device calculates the interpolation / decimation coefficients and the number of steps of the device.

The number of operation steps of the device is supplied to the comparison device 1 (block 10), the decimation coefficient of the signal is fed to the first input of the signal interpolation / decimation block (block 8), the signal interpolation coefficient is fed to the second input of the signal interpolation / decimation block (block 8).

After arriving at the block for performing interpolation / decimation of the signal (block 8) of the synchronization signal of the start of calculations, the block performs the calculation. The resulting signal is input to the key

(block 2), the signal that the operation was performed is fed to the input of addition device 1 (block 9).

After the input of the comparison device 1 (block 10) of the synchronization signal for performing the comparison, the device compares the value located at its first input with the value located at its second input, if the value at the second input is equal to the value at the first input, then the comparison device generates at the device’s output, a logical unit that arrives at the control and address generation unit and the device completes its work; otherwise, the device controlled by the control and address generation unit does the same Action been consistent processing signal which is output from the unit performing interpolation / decimation signal (block 8), as long as the value at the first input does not equal the value on the second input.

The unit for computing the signal processing parameters (block 7) operates as follows.

According to the general initialization signal, zero values are supplied to the inputs of all devices and the internal registers of the addition devices are reset, the value of the internal register of the addition device 4 (block 7.8) is set to 1.

According to the synchronizing signal for downloading data to the division device 3 (block 7.10), a constant value is loaded to the first input (the value of the constant value is 100), and the cut-off signal power is loaded to the second input. According to the clock signal of division, the division device 3 (block 7.10) performs the division of the value located at the first input by the value located at the second input. The output of the division device 3 (block 7.10) is the first output of the signal processing parameter calculation unit (block 7).

According to the synchronizing signal of downloading data to the device of multiplication 2 (block 7.11) to the first input, the value from the output of the device

addition 4 (block 7.8), the value of the cut-off signal power is loaded to the second input. According to the synchronization signal of the multiplication device multiplication 2 (block 7.11) performs the multiplication of the values located on the first and second inputs of the device.

According to the synchronizing data loading signal, a one-dimensional discrete signal s [n] is received from the key output (block 2) to the device for calculating the fast one-dimensional Fourier transform (block 7.1). Using the synchronization signal of the calculation, the device calculates the Fourier transform of the original signal. Then, upon receipt of a data output signal to addition device 2 (block 7.2), the device begins to perform element-wise output of samples of the signal spectrum. When synchronization signals of addition arrive at addition device 2 (block 7.2), the device performs addition of discrete samples arriving at its input with the value of the internal register.

After adding up all the elements of the spectrum, the sum of the values of the spectrum samples is formed at the output of the addition device 2 (block 7.2). According to the synchronizing signal for downloading data received at the synchronization input of the addition device 3 (block 7.3), the next value of the signal spectrum reading is fed to the input of the block. According to the synchronization signal of addition, which is input to the synchronization input of addition device 3 (block 7.3), the value at the input of the device (the next value of the signal spectrum spectrum) is added to the value stored in the internal register of addition 3 (block 7.3).

According to the synchronization signal of the division arriving at the division device 1 (block 7.4), the division of the value supplied to the second input of the division device 1 (block 7.4) is performed by the value supplied to the first input of the division device 1 (block 7.4). The result of the division is fed to the second input of the comparison device 2 (block 7.6) and to the first input of the division device 2 (block 7.7).

When a synchronizing signal for loading data arrives at the third input of the device of comparison 2, the first input of the device of comparison 2 (block 7.6) receives the result of the operation of the multiplier 2 (block 7.11), and the second input receives the value from the output of the division device 1 (block 7.4). Upon receipt of the synchronization comparison signal to the comparison device 2 (block 7.6), the correctness of the fact that the value supplied to the second input is greater than the value applied to the first input is checked. Thus, if the value at the first input is greater than the value at the second input, then 1 is formed at the output of the comparison device 2 (block 7.6), otherwise 0. The result of the device’s operation is transferred to the addition device 4 (block 7.8), which is added by the synchronization signal of addition values at the first input with the value of the internal register. The control and address generation unit (block 11) analyzes the value at the output of the comparison device 2 (block 7.6). If 0 is located at the output of the comparison device 2 (block 7.6), then the control and address generation block (block 11) sends to the device the calculation of the fast one-dimensional Fourier transform (block 7.1), the synchronization signal of the output of the next element of the spectrum.

This process will be repeated until 1. appears at the output of comparison device 2 (block 7.6). If 1 is at the output of comparison device 2 (block 7.6), then the control and address generation unit (block 11) sends 3 to the summation device (block 7.3) a synchronization signal for outputting a value stored in the internal register to the multiplier 1 (block 7.5). Upon receipt of a synchronization signal for calculating the operation of multiplication on the multiplication device 1 (block 7.5), the device multiplies the values supplied to its inputs, i.e. values from the second output of the summing device 2, i.e. the number of summed samples, the values from the output of the multiplier 2 (block 7.11) and the result of the operation of the comparison device 2 (block 7.6).

According to the synchronizing signal for downloading data, the value from the output of the multiplier 1 (block 7.5) is fed to the second input of the division device 2 (block 7.7), and the value calculated in the division device is supplied to the first input of the division device 2 (block 7.7) according to the synchronizing signal for loading data 1 (block 7.4). According to the synchronization signal of division received at the input of division 2 (block 7.7), the value received at the second input of division 2 (block 7.7) is divided by the value received at the first input of division 2 (block 7.7). The result of the operation of the device is supplied to the block for calculating the interpolation / decimation coefficients.

By the synchronizing load signal, the value from the output of division device 2 (block 7.7) is loaded into the block for calculating the interpolation / decimation coefficients of the signal (block 7.9). The interpolation / decimation device calculates the interpolation / decimation coefficients of the signal from the synchronization signal for performing the calculations. The first output of the signal interpolation / decimation coefficient calculation unit (block 7.9) is the second output of the signal processing parameter calculation unit, the second output is the third output of the signal processing parameter calculation unit.

Let us consider in more detail the operation of the block for calculating the interpolation / decimation coefficients (block 7.9).

The input signal of the calculation of the coefficients of interpolation / decimation from the output of the division device 2 (block 7.7) receives the coefficient of thinning signal.

Using the synchronizing signal for downloading data coming to the third input of the comparison device 3 (block 7.9.1), the signal thinning coefficient is downloaded from the output of the division device 2 (block 7.7) to the second input of the comparison device 3 (block 7.9.1).

Using the synchronizing signal for downloading data coming to the third input of the comparison device 4 (block 7.9.2), the coefficient of thinning of the signal from the output of the division device 2 (block 7.7) is downloaded to the second input of the comparison device 4 (block 7.9.2).

By the synchronizing signal of the data loading coming to the third input of the comparison device 5 (block 7.9.3), the signal thinning coefficient is downloaded from the output of the division device 2 (block 7.7) to the second input of the comparison device 5 (block 7.9.3).

By a synchronizing signal for downloading data coming to the third input of the comparison device 6 (block 7.9.4), the signal thinning coefficient is downloaded from the output of the division device 2 (block 7.7) to the second input of the comparison device 6 (block 7.9.4).

Using the synchronizing signal to perform the comparison operation, which is input to the third input of the comparison device 3 (block 7.9.1), the comparison device 3 (block 7.9.1) verifies that the value at the second input of the device is less than the value at the first input of the device (at the first input of the device constant 0.1 is loaded). If the value at the second input of the device is less than the value at the first input of the device, then 1 is supplied to the output of the device, otherwise 0.

Using the synchronizing signal to perform the comparison operation, which is input to the third input of the comparison device 4 (block 7.9.2), the comparison device 4 (block 7.9.2) verifies that the value at the second input of the device is greater than the value at the first input of the device (at the first input of the device constant 0.01 is loaded). If the value at the second input of the device is greater than the value at the first input of the device, then 1 is output to the output of the device, otherwise 0.

Using the synchronizing signal to perform the comparison operation, which is input to the third input of the comparison device 5 (block 7.9.3), the comparison device 5 (block 7.9.3) verifies that the value at the second input of the device is greater than or equal to the value at the first input of the device (at

the first input of the device is loaded constant 0.1). If the value at the second input of the device is greater than or equal to the value at the first input of the device, then 1 is output to the output of the device, otherwise 0.

Using the synchronizing signal to perform the comparison operation, which is supplied to the third input of the comparison device 6 (block 7.9.4), the comparison device 6 (block 7.9.4) verifies that the value at the second input of the device is greater than or equal to the value at the first input of the device (at the first device input is loaded constant 0.01). If the value at the second input of the device is less than the value at the first input of the device, then 1 is supplied to the output of the device, otherwise 0.

According to the synchronizing data loading signal, which is supplied to the fourth input of the multiplying device 3 (block 7.9.5), the value from the output of the comparison device 3 (block 7.9.1) is downloaded to the second input, the value from the output of the comparison device 4 is loaded to the third input (block 7.9 .2), a constant value is loaded at the first input (the constant value is 1000).

According to the synchronization signal of the multiplication, the multiplying device 3 (block 7.9.5) performs the multiplication of the quantities located at its inputs. The resulting value goes to the output of the multiplier 3 (block 7.9.5).

According to the synchronizing data loading signal, which is supplied to the third input of the multiplying device 4 (block 7.9.6), the value from the output of the comparison device 4 (block 7.9.3) is loaded to the second input, a constant value is loaded to the first input (the constant value is 100).

According to the synchronization signal of the multiplication, the multiplying device 4 (block 7.9.6) performs the multiplication of the quantities located at its inputs. The resulting value goes to the output of the multiplying device 4 (block 7.9.6).

According to the synchronizing data loading signal, which is supplied to the third input of the multiplier 5 (block 7.9.7), the value from the output of the comparison device 6 (block 7.9.4) is loaded to the second input, a constant value is loaded to the first input (the constant value is 10000).

According to the synchronization signal of the multiplication, the multiplying device 5 (block 7.9.7) performs the multiplication of the quantities located at its inputs. The resulting value goes to the output of the multiplier 5 (block 7.9.7).

According to the synchronizing signal of the data loading received at the multiplier 6 (block 7.9.8), the value from the output of the multiplier 3 (block 7.9.5) is loaded to the first input, and the signal thinning coefficient from the output of the divider 2 is transmitted to the second input (block 7.7).

According to the synchronization signal of multiplication, which is input to the synchronization input of the device of multiplication 6 (block 7.9.8), the device performs the multiplication of the values located at its inputs, the result of the work goes to the output of the device.

According to the synchronizing signal of the data loading received at the multiplying device 7 (block 7.9.9), the value from the output of the multiplying device 4 (block 7.9.6) is loaded to the first input, and the signal thinning coefficient from the output of the division device 2 (block is input to the second input) 7.7).

According to the synchronization signal of multiplication, which is input to the synchronization input of the device of multiplication 7 (block 7.9.9), the device performs the multiplication of the values located at its inputs, the result of the work goes to the output of the device.

According to the synchronizing signal of the data loading received at the multiplier 8 (block 7.9.10), the value from the output of the multiplier 5 (block 7.9.7) is loaded to the first input, and to the second input

- coefficient of thinning signal from the output of the division device 2 (block 7.7).

According to the synchronization signal of multiplication, which is input to the synchronization input of the device of multiplication 8 (block 7.9.10), the device performs the multiplication of the values located at its inputs, the result of the work goes to the output of the device.

According to the synchronizing signal of the data loading received at the addition device 5 (block 7.9.11), the value from the output of the multiplying device 6 (block 7.9.8) is downloaded to the first input, and the value from the output of the multiplying device 7 (block 7.9.9) is loaded to the second input ), and to the third input - the value from the output of the multiplying device 8 (block 7.9.10).

According to the synchronization signal of addition to the input of the synchronization device of addition 5 (block 7.9.11), the device performs the addition of the values located at its inputs. The result of the operation of addition device 5 (block 7.9.11) is the decimation coefficient of the signal.

According to the synchronizing signal of the data loading received at the addition device 6 (block 7.9.12), the value from the output of the multiplier 3 (block 7.9.5) is loaded onto the first input, and the value from the output of the multiplier 4 (block 7.9.6) is loaded onto the second input ), and to the third input, the value from the output of the multiplying device 5 (block 7.9.7).

According to the synchronizing addition signal received at the synchronization input of the addition device 6 (block 7.9.12), the device performs the addition of the values at its inputs. The result of the operation of the addition device 6 (block 7.9.12) is the signal interpolation coefficient.

The block for performing interpolation / decimation of the signal (block 8) operates as follows.

According to the synchronizing load signal, which is input to the synchronization input of the interpolation device (block 8.1), the signal from the output of the convolution device 2 (block 6) is supplied to the first input of the interpolation device (block 8.1), and the signal interpolation coefficient from the third output of the calculation block is supplied to the second input of the interpolation device signal processing parameters (block 7). According to the synchronization signal for performing the interpolation operation, which is input to the synchronization input of the interpolation device (block 8.1), the device interpolates the signal received at the first input with the coefficient received at the second input. The result of the operation of the interpolation device (block 8.1) is fed to the second input of the decimation device (block 8.2). According to the synchronizing signal for loading data, which is input to the synchronization input of the decimation device (block 8.2), the decimation coefficient is loaded onto the first input of the device.

According to the synchronization signal of the decimation operation to the synchronization input of the decimation device (block 8.2), the device decimates the signal received at the second input with the coefficient received at the first input. The result of the operation of the decimation device (block 8.2) is the result of the operation of the adaptive wavelet transform computation device.

Thus, this device allows you to get a set of low-frequency and high-frequency components of the signal using the signal scaling factor, adaptive to the characteristics of the signal.

Claims (1)

An adaptive wavelet transform calculation device comprising an analog-to-digital converter, read-only memory 1, read-only memory 2, fast one-dimensional Fourier transform calculation device, characterized in that a key, a convolution unit 1, a convolution unit 2, a processing parameter calculation unit are additionally entered the signal, the block interpolation / decimation of the signal, the addition device 1, the comparison device 1, the control unit and the generation of addresses, and the input of the analog-to-digital pre the analyzer receives the analyzed signal, the output of the analog-to-digital converter is connected to the first input of the key, the output of the key is connected to the first input of the convolution unit 1, to the first input of the convolution unit 2, to the second input of the signal processing parameter calculation unit, the output of the permanent storage device 1 is connected to the second the input of convolution block 1, the output of read-only memory 2 is connected to the second input of convolution block 2, the output of convolution block 1 is the first output of the device, the output of convolution block 2 is connected to the third input ohm of the signal interpolation / decimation unit, the cut-off signal power is supplied to the first input of the signal processing parameter calculation unit, the first output of the signal processing parameter calculation unit is connected to the first input of the comparison device 1, the second output of the signal processing parameter calculation unit is connected to the first input of the interpolation unit / signal decimation, the third output of the signal processing parameter calculation unit is connected to the second input of the signal interpolation / decimation unit, the first output of the interpolation / de block the signal citation is connected to the first input of the addition device 1, the second output of the interpolation / decimation unit of the signal is connected to the second input of the key and is the second output of the adaptive wavelet transform calculation device, the output of the addition device 1 is connected to the second input of the comparison device 1, the output of the comparison device 1 is connected with a control unit and generating addresses, and the control unit and generating addresses is connected to all of the above blocks, and the unit for calculating the signal processing parameters contains triad of calculating fast one-dimensional Fourier transform, addition device 2, addition device 3, division device 1, multiplication device 1, comparison device 2, division device 2, addition device 4, interpolation / decimation coefficient calculation unit, division device 3, multiplication device 2, moreover, a signal from the key output is supplied to the input of the fast Fourier transform calculation device, the output of the fast Fourier transform calculation device is connected to the first input of addition device 2 and the third the input of the device 3, the output of the device 2 is connected to the first input of the device 1, the first output of the device 3 is connected to the second input of the device 1, the second output of the device 3 is connected to the third input of the multiplier 1, the output of the device 1 is connected to the second the input of the device of comparison 2 and with the first input of the device of division 2, the output of the device of multiplication 1 is connected to the second input of the device of division 2, the output of the device of comparison 2 is connected to the first input of the device of multiplication I 1 and with the first input of the addition device 4, the output of the addition device 4 is connected to the first input of the multiplier 2, the output of the division device 2 is connected to the first input of the interpolation / decimation coefficient calculation unit, the first output of the signal interpolation / decimation calculation unit is the second output the signal processing parameter calculation unit, the second output of the signal interpolation / decimation coefficient calculation unit is the third output of the signal processing parameter calculation unit, to the first in the stroke of the division device 3 is supplied with a constant value (the value of the constant supplied to the input of the device is 100), the cut-off signal power is supplied to the second input of the division device 3, the output of the division device 3 is the first output of the signal processing parameter calculation unit, and the second input of the multiplier 2, the cutoff power of the signal is supplied, the output of the multiplier 2 is connected to the second input of the multiplier 1 and to the first input of the comparison device 2, and the coefficient calculation unit The interpolation / decimation element includes a comparison device 3, a comparison device 4, a comparison device 5, a comparison device 6, a multiplication device 3, a multiplication device 4, a multiplication device 5, a multiplication device 6, a multiplication device 7, a multiplication device 8, an addition device 5 , the addition device 6, and at the first input of the comparison device 3 receives a constant value (the value of the constant supplied to the input of the device is 0.1), the second input of the comparison device 3 receives a value from the output the ode of division device 2, the output of the comparison device 3 is connected to the second input of the multiplying device 3, a constant value is supplied to the first input of the comparison device 4 (the value of the constant supplied to the input of the device is 0.01), the second input of the comparison device 4 is connected to the output of the device division 2, the output of the comparison device 4 is connected to the third input of the multiplying device 3, a constant value is supplied to the first input of the comparison device 5 (the value of the constant supplied to the input of the device is 0.1), the second input of the device the comparison unit 5 is connected to the output of the division device 2, the output of the comparison device 5 is connected to the second input of the multiplying device 4, a constant value is supplied to the first input of the comparison device 6 (the value of the constant supplied to the input of the device is 0.01), the second input of the comparison device 6 is connected to the output of the division device 2, the output of the comparison device 6 is connected to the second input of the multiplying device 5, a constant value (the value of the constant supplied to the input equal to 1000), the output of the multiplier 3 is connected to the first input of the multiplier 6 and to the first input of the addition device 6, a constant value is supplied to the first input of the multiplier 4 (the value of the constant supplied to the input of the device is 100), the output of the multiplier 4 is connected to the first input of the multiplying device 7 and to the second input of the addition device 6, a constant value is supplied to the first input of the multiplying device 5 (the value of the constant supplied to the input of the device is 10000), the output of the device of multiplication 5 is connected to the first input of the multiplying device 8 and to the third input of the addition device 6, the second input of the multiplying device 6 receives the value from the output of the division device 2, the output of the multiplying device 6 is connected to the first input of the adding device 5, to the second input of the multiplying device 7 the value comes from the output of the division device 2, the output of the multiplying device 7 is connected to the second input of the addition device 5, the second input of the multiplying device 8 receives the value from the output of the division device 2, the course of the multiplier 8 is connected to the third input of the addition device 5, the output of the addition device 5 is the first output of the adaptive wavelet transform calculation device, the output of the addition device 6 is the second output of the adaptive wavelet transform calculation device, the signal interpolation / decimation execution unit comprising an interpolation device and a decimation device, and a signal from the output of the convolution device 2 is supplied to the first input of the interpolation device, and to the second input of the interpo device the signal interpolation coefficient is supplied from the third output of the signal processing parameter calculation unit, the interpolation device output is connected to the second input of the decimation device, the signal decimation coefficient is fed to the first input of the decimation device from the second output of the signal processing parameter calculation block, the first output of the decimation device is connected to the second input comparison device 1, the second output of the decimation device is the output of the adaptive wavelet transform calculation device.