KR102457573B1 - Apparatus and method for generating of noise signal, computer-readable storage medium and computer program - Google Patents

Abstract

The noise signal generating apparatus of the embodiment includes a noise signal generator generating a noise source signal of a specific frequency bandwidth, and generating a multi-noise signal by expanding the noise source signal to a noise source signal having an equal frequency interval in the specific frequency band. It may include a multi-noise signal generator and a randomizer that randomizes and outputs the multi-noise signal.
In addition, the noise signal generating apparatus of the embodiment includes a noise signal generating unit generating a noise source signal of a specific frequency bandwidth, and extending the noise source signal to a noise source signal having unequal frequency intervals in the specific frequency band to obtain a multi-noise signal. a multi-noise signal generator for generating can do.

Description

Apparatus and method for generating noise signal, computer readable recording medium and computer program

The embodiment relates to a multi-band noise signal generation, and more particularly, to a noise signal generation method and apparatus for generating a noise signal of various bandwidths.

In general, in Electronic Warfare (EW), Electronic Attack (EA) uses the location information of the enemy threat signal acquired through Electronic Support (ES) to generate high-power electronic jamming in the direction of the location. (Electronic Jamming) It is performed by a method of transmitting a signal or an electromagnetic only (Electronic Deception) signal.

The high-power electronic jamming signal used for such an electronic attack is generated by using a noise signal generated according to the bandwidth of a signal to be attacked in a frequency band requiring an electronic attack.

A noise signal for an electronic attack can be used for an effective electronic attack only when it has uniform frequency characteristics within a desired bandwidth in a desired frequency band. This is because, when a specific pattern exists in the generated noise signal or the frequency characteristic is uneven, the threat of receiving an electronic attack can recognize the characteristic factors and nullify the electronic attack. Therefore, as the characteristics of the noise signal generated for the electronic attack are closer to the characteristics of additive white Gaussian noise (AWGN), it can be used as a signal suitable for an effective electronic attack.

In order to solve the above-mentioned problems, an object of the embodiment is to provide a noise signal generating method and apparatus for simultaneously generating a noise signal used for an electronic attack in a plurality of frequency bands with low complexity.

The noise signal generating apparatus of the embodiment includes a noise signal generator generating a noise source signal of a specific frequency bandwidth, and generating a multi-noise signal by expanding the noise source signal to a noise source signal having an equal frequency interval in the specific frequency band. It may include a multi-noise signal generator and a randomizer that randomizes and outputs the multi-noise signal.

In addition, the noise signal generating apparatus of the embodiment includes a noise signal generating unit generating a noise source signal of a specific frequency bandwidth, and extending the noise source signal to a noise source signal having unequal frequency intervals in the specific frequency band to obtain a multi-noise signal. a multi-noise signal generator for generating can do.

Further, an embodiment provides a noise signal generating method performed in a noise signal generating apparatus, comprising: generating a noise source signal sequence; converting the noise source signal sequence into a phase sample value sequence controlled with a specific frequency bandwidth; generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence; and generating a multi-noise signal by expanding the noise source signal into a noise source signal having an equal frequency interval in the specific frequency band. and randomizing and outputting the multi-noise signal.

Further, an embodiment provides a noise signal generating method performed in a noise signal generating apparatus, comprising: generating a noise source signal sequence; converting the noise source signal sequence into a phase sample value sequence controlled with a specific frequency bandwidth; , generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence, and generating a multi-noise signal by expanding the noise source signal to a noise source signal having unequal frequency intervals in the specific frequency band. The method may include randomizing and outputting the multi-noise signal, and extracting a multi-noise signal having a positive frequency component from among the randomized multi-noise signals.

Another embodiment is a computer-readable recording medium storing a computer program, the computer program, when executed by a processor, comprises the steps of: generating a noise source signal sequence, and controlling the noise source signal sequence to a specific frequency bandwidth converting the phase sample value sequence into a sequence of phase sample values; generating a noise source signal having a specific frequency bandwidth based on the phase sample value sequence; and converting the noise source signal to a noise source signal having equal frequency intervals in the specific frequency band. The processor may include instructions for causing the processor to perform an operation including generating a multi-noise signal by expanding to ? and randomizing and outputting the multi-noise signal.

An embodiment also provides a computer readable medium having a computer program stored thereon, comprising the steps of: generating a noise source signal sequence, converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence; and generating a multi-noise signal by expanding the noise source signal into a noise source signal having unequal frequency intervals in the specific frequency band. The processor performs a method comprising: randomizing and outputting the multi-noise signal; and extracting a multi-noise signal having a positive frequency component from among the randomized multi-noise signals. It may contain instructions for doing so.

Further, an embodiment is a computer program stored in a computer-readable recording medium, wherein the computer program, when executed by a processor, includes generating a noise source signal sequence and controlling the noise source signal sequence to a specific frequency bandwidth. converting the phase sample value sequence into a sequence of phase sample values; generating a noise source signal having a specific frequency bandwidth based on the phase sample value sequence; and converting the noise source signal to a noise source signal having equal frequency intervals in the specific frequency band. The processor may include instructions for causing the processor to perform an operation including generating a multi-noise signal by expanding to ? and randomizing and outputting the multi-noise signal.

Further, there is provided a computer program stored on a computer-readable recording medium, comprising the steps of: generating a noise source signal sequence; converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; generating a noise source signal of a specific frequency bandwidth based on a sequence of values; and generating a multi-noise signal by expanding the noise source signal into a noise source signal having unequal frequency intervals in the specific frequency band; For causing a processor to perform a method comprising the steps of outputting a randomized multi-noise signal and extracting a multi-noise signal of a positive frequency component from among the randomized multi-noise signals It may contain instructions.

The embodiment generates a noise signal in a plurality of frequency bands using a noise source signal and applies a randomization characteristic of the noise signal through a convolution operation with a pseudo-random sequence, so that a specific pattern does not exist in the generated noise signal. There is an effect of generating a multi-band noise signal similar to white noise with an even frequency characteristic.

In addition, in the embodiment, only necessary noise signals may be selectively generated among noise signals symmetrically generated in a baseband by applying a Hilbert transform to the generated noise signals.

1 is a block diagram illustrating an apparatus for generating a noise signal according to a first embodiment.
2 is a block diagram illustrating a noise signal generating unit of the noise signal generating apparatus according to the first embodiment.
3 is a block diagram illustrating a sequence generator of the noise signal generator of FIG. 2 .
4 is a block diagram illustrating an apparatus for generating a noise signal according to a second embodiment.
5A is a diagram illustrating a power spectrum of an output signal when a random noise source signal having a bandwidth of 20 MHz is generated by a noise signal generator.
5B is a diagram illustrating a power spectrum of an output signal when a random noise source signal having a bandwidth of 100 MHz is generated by a noise signal generator.
6A is a graph illustrating a sample waveform of an input signal of a phase sample value generator before bandwidth control in a noise signal generator.
FIG. 6B is a graph illustrating a sample waveform of an output signal of a phase sample value generator when the noise signal generator controls with a 20 MHz bandwidth.
7A is a graph illustrating a phase sample waveform of an output signal when a random noise source signal having a bandwidth of 20 MHz is generated by a noise signal generator.
7B is a graph illustrating an in-phase component sample waveform of an output signal when the noise signal generator generates a random noise source signal having a bandwidth of 20 MHz.
7C is a graph illustrating a quadrature component sample waveform of an output signal when a random noise source signal having a bandwidth of 20 MHz is generated by the noise signal generator.
FIG. 8a shows a case in which two band noise signals are generated at 50 MHz frequency intervals using a random noise source signal having a bandwidth of 20 MHz using a multi-band noise signal generator before convolution with a pseudo-random sequence c ( n ) is performed. It is a graph showing the power spectrum of a multi-band noise signal.
8B shows a case in which two band noise signals at 50 MHz frequency intervals using a random noise source signal having a bandwidth of 20 MHz are generated using a multi-band noise signal generator, after convolution with a pseudo-random sequence c ( n ) is performed. It is a graph showing the power spectrum of a multi-band noise signal.
9A is a graph illustrating a power spectrum of a multi-band noise signal when a noise signal generator generates four band noise signals at equal frequency intervals of 50 MHz using a random noise source signal having a bandwidth of 20 MHz.
9B is a graph illustrating a power spectrum of a multi-band noise signal when an 8-band noise signal is generated using a noise signal generator at an equal frequency interval of 50 MHz using a random noise source signal having a bandwidth of 20 MHz.
FIG. 9C is a graph illustrating a power spectrum of a multi-band noise signal when a noise signal generator generates 16 band noise signals at an equal frequency interval of 50 MHz using a random noise source signal having a bandwidth of 20 MHz.
10A shows a convolution operation with a pseudo-random sequence c ( n ) and Hilbert transform when a multi-band noise signal is generated using a multi-band noise signal generator at unequal frequency intervals using a 50 MHz bandwidth random noise source signal. It is a graph showing the power spectrum of a multi-band noise signal when ?
10b shows that when a multi-band noise signal is generated at unequal frequency intervals using a random noise source signal of a 50 MHz bandwidth using a multi-band noise signal generator, a convolution operation with a pseudo-random sequence c ( n ) is not applied. It is a graph showing the power spectrum of a multi-band noise signal when the Hilbert transform is applied without
10C is a graph illustrating a power spectrum of a multi-band noise signal when a multi-band noise signal is generated using a multi-band noise signal generator at unequal frequency intervals using a random noise source signal having a bandwidth of 50 MHz.
11A is a power spectrum of the same mass-band noise signal as in FIG. 9C, and FIG. 11B is a graph illustrating a power spectrum when the center frequency of the generated multi-band noise signal is frequency-shifted to a DC frequency.
12 is a flowchart illustrating a method for generating a noise signal according to the first embodiment.
13 is a flowchart illustrating a method of generating a noise signal according to the second embodiment.

Hereinafter, the embodiment will be described in detail with reference to the drawings.

1 is a block diagram showing a noise signal generating apparatus according to a first embodiment, FIG. 2 is a block diagram showing a noise signal generating unit of the noise signal generating apparatus according to the first embodiment, and FIG. 3 is the noise signal of FIG. It is a block diagram showing the sequence generator of the generator.

Referring to FIG. 1 , the noise signal generating apparatus 1000 according to the first embodiment may include a noise signal generating unit 100 , a multiple noise signal generating unit 200 , and a randomizing unit 300 .

The noise signal generator 100 may generate a noise source signal s(n) of a desired bandwidth, eg, a specific bandwidth, with low complexity without using a digital filter.

를 생성할 수 있다.The multi-noise signal generating unit 200 expands the noise source signal into a multi-band signal having an equal frequency interval in a desired frequency band to obtain a multi-noise signal.

can create

The randomizer 300 may randomize and output a noise signal of a specific bandwidth, which is a desired bandwidth, generated by the multi-noise signal generator 200 .

The randomizer 300 may randomize multiple noise source signals of a specific bandwidth through a convolution operation on a pseudo-random sequence. Alternatively, the randomizer 300 may perform randomization through a convolution operation on a noise signal of a specific bandwidth and a Constant Amplitude Zero Auto-Correlation Sequence (CAZAC) sequence.

The noise source signal of a specific bandwidth desired by the noise signal generating apparatus 1000 according to the embodiment may be defined as a random noise signal generated with a complex Gaussian distribution or a uniform distribution.

When a random noise source signal generated with a complex Gaussian distribution or a uniform distribution is s ( n ), the noise signal generator 100 does not apply a digital filter and does not apply a BW _Noise MHz bandwidth band- It is possible to generate a limited noise source signal s ( n ).

As shown in FIG. 2 , the noise signal generator 100 according to the embodiment includes a sequence generator (PRN Sequence Generator, 110), a phase sample value generator (130), and a numerically controlled oscillator (Numerically). -Controlled Oscillator, 150) may be included.

The sequence generator 110 may generate a noise source signal sequence. The sequence generator 110 for generating the noise source signal sequence may include an N _bit random signal generator 111 for generating basic unit noise having a 1 kHz bandwidth, and as shown in FIG. 3 , a plurality of It may include a random signal generator 111 and a comparator 113 .

The phase sample value generator 130 may generate a phase sample value sequence controlled by a noise source signal sequence with a specific frequency bandwidth. The noise source signal sequence may be generated by being converted into a phase sample value sequence controlled with a desired specific bandwidth BW _Noise in the baseband through the phase sample value generator 130 .

At this time, in order to generate a sequence of phase sample values controlled with a specific desired bandwidth, a conversion expression value (BCV: Bandwidth Control Value) as in Equation 1 is multiplied by the noise source signal sequence.

[Equation 1]

Here, N _bit may mean a bit value, BW _noise may mean a desired bandwidth, and _fs may mean a sampling frequency.

The numerically controlled oscillator 150 may generate a noise source signal of a desired specific frequency bandwidth based on a sequence of phase sample values. The numerical control oscillator 150 may output I/Q data of the noise source signal s(n) as in Equation 2 through a modular operation of the p(n) value calculated through the phase accumulation operation.

[Equation 2]

를 생성할 수 있다.Returning to FIG. 1 , the multi-noise signal generator 200 expands the noise source signal into a noise signal with equal frequency intervals in a specific frequency band to obtain a multi-noise source signal.

can create

The multi-noise signal generator 200 may include a bandwidth extension signal generator that generates a bandwidth extension signal, and a logic operator that generates a noise signal of a specific bandwidth through an OR operation on the noise source signal and the bandwidth extension signal. However, the present invention is not limited thereto.

로 변환될 수 있다. 즉, 다중 대역의 다중 잡음 소스 신호

은 잡음 소스 신호 s(n)과 코사인 함수들의 곱셈 연산으로 발생되며, 잡음 소스 신호 s(n)의 대역폭 BW _Noise MHz값에 의하여 다수개의 주파수 대역에 발생된 잡음 신호들 각각의 대역폭이 동일하게 결정될 수 있다.The noise source signal s(n) is a multiple noise source signal generated in a plurality of frequency bands required through a cosine function multiplication operation as shown in Equation 3

can be converted to That is, multiple noise source signals in multiple bands.

is generated by multiplying the noise source signal s ( n ) and cosine functions, and the bandwidth BW of the noise source signal s ( n ) is BW _Noise . The bandwidth of each of the noise signals generated in a plurality of frequency bands may be equally determined by the MHz value.

[Equation 3]

Here, d is a frequency interval between noise source signals generated in a plurality of frequency bands, and f _s is a sampling frequency. In Equation 3, when cosine function multiplication is performed K times, 2 ^K multi-band noise source signals may be generated.

에서 다수개 주파수 대역에 발생된 각각의 BW _Noise MHz 대역폭을 갖는 잡음 신호는 모두 유사한 주파수 특성 패턴을 갖게 된다. 이와 같은 현상을 최소화하고 랜덤화하기 위하여 생성된 다중 대역 잡음 신호

과 의사 랜덤 시퀀스 c(n)을 이용하여 컨볼루션 연산부에서 수학식 4의 무작위화(Randomization) 연산을 수행한다.Generated multi-band noise signal

Each BW _noise generated in multiple frequency bands in All noise signals having a MHz bandwidth have similar frequency characteristic patterns. Multi-band noise signal generated to minimize and randomize this phenomenon

and the pseudo-random sequence c ( n ), the convolution operator performs the randomization operation of Equation (4).

[Equation 4]

The pseudo-random sequence c ( n ) used for randomization is a pseudo noise sequence in which a normalized value of -1 or 1 is used for randomization or a CAZAC sequence (Constant Amplitude Zero) that generates a random signal sequence in complex numbers. Auto-Correlation Sequence) may be utilized.

4 is a block diagram illustrating an apparatus for generating a noise signal according to a second embodiment.

Referring to FIG. 4 , the noise signal generating apparatus 2000 according to the second embodiment includes a noise signal generating unit 2100 , a multiple noise signal generating unit 2200 , a randomizing unit 2300 , and a Hilbert transform (Hilbert transform). Transform) operation unit 2400 may be included. Here, since the configuration except for the multiple noise signal generator and the Hilbert transform calculator is the same as that of the noise signal generator according to the first embodiment, a detailed description thereof will be omitted.

를 생성할 수 있다.The multi-noise signal generator 2200 expands the noise source signal into a noise signal with non-uniform frequency intervals in a specific frequency band to obtain a multi-noise source signal.

can create

The multi-noise signal generator 2200 may include a bandwidth extension signal generator that generates a bandwidth extension signal, and a logic operator that generates a noise signal of a specific bandwidth through an OR operation on the noise source signal and the bandwidth extension signal. However, the present invention is not limited thereto.

로 변환될 수 있다. 즉, 다중 대역의 다중 잡음 소스 신호

은 잡음 소스 신호 s(n)과 코사인 함수들의 곱셈 연산으로 발생되며, 잡음 소스 신호 s(n)의 대역폭 BW _Noise MHz값에 의하여 다수개의 주파수 대역에 발생된 잡음 신호들 각각의 대역폭이 동일하게 결정될 수 있다.The noise source signal s(n) is a multiple noise source signal generated in a plurality of frequency bands required through a cosine function multiplication operation as shown in Equation 5.

can be converted to That is, multiple noise source signals in multiple bands.

is generated by multiplying the noise source signal s ( n ) and cosine functions, and the bandwidth BW of the noise source signal s ( n ) is BW _Noise . The bandwidth of each of the noise signals generated in a plurality of frequency bands may be equally determined by the MHz value.

[Equation 5]

Here, f _k is a center frequency between noise signals generated in a plurality of frequency bands, and f _s is a sampling frequency. In Equation 5, when cosine function multiplication is performed K times, K multi-band noise source signals may be simultaneously generated symmetrically in the baseband and in the negative and positive frequency bands.

에서 다수개 주파수 대역에 발생된 각각의 BW _Noise MHz 대역폭을 갖는 잡음 신호는 모두 유사한 주파수 특성 패턴을 갖게 된다. 이와 같은 현상을 최소화하고 랜덤화하기 위하여 생성된 다중 대역 잡음 신호

과 의사 랜덤 시퀀스 c(n)을 이용하여 컨볼루션 연산부에서 무작위화(Randomization) 연산을 수행한다.Generated multi-band noise signal

Each BW _noise generated in multiple frequency bands in All noise signals having a MHz bandwidth have similar frequency characteristic patterns. Multi-band noise signal generated to minimize and randomize this phenomenon

and a pseudo-random sequence c ( n ) to perform a randomization operation in the convolution operation unit.

The Hilbert transform operation unit 2400 may remove a noise signal of an unnecessary frequency band from the multi-noise source signal extended by non-uniform frequency intervals.

을 힐베르트 변환 연산부(2400)에서 입력받은 뒤, 필요로 하는 양의 주파수 성분의 다중 대역 잡음 신호만을 사용하기 위하여 힐베르트 변환을 적용할 수 있다.Noise source signal generated symmetrically with positive and negative frequencies at baseband through randomization

After receiving from the Hilbert transform operator 2400 , the Hilbert transform may be applied to use only a multi-band noise signal having a required amount of frequency component.

When a random noise source signal having a bandwidth of BW _Noise = 20 MHz is generated using the low-complexity bandwidth control noise signal generator 100 according to the embodiment, the power spectrum of the output signal is as shown in FIG. 5A, and BW _Noise = 100 MHz bandwidth The power spectrum of the random noise source signal of is shown in FIG. 5B.

The input signal sample waveform of the phase sample value generator 130 before bandwidth control used to generate a random noise source signal showing a power spectrum of BW _Noise = 20 MHz of FIG. 5B is generated as shown in FIG. 6A, and BW _Noise = 20 When bandwidth control of MHz is applied, the output signal sample waveform of the phase sample value generator 130 is generated as shown in FIG. 6B .

N _Bit = generated using a 32-bit random signal generator (111) at f _s = 200 MHz sampling frequency, and the value of the bandwidth control conversion equation in Equation 1 BCV = 2 ³² × 20 / 200 = 4.3 × 2 ⁸ is multiplied by the noise signal source sequence to be used as the phase sample value sequence.

The phase sample value sequence generated after bandwidth control is applied is input to the numerical control oscillator 150, and the generated phase sample waveform of the noise source signal s ( n ) is as shown in FIG. 7A , and in this case, the An in-phase component sample waveform is shown in FIG. 7B , and a quadrature component sample waveform of the noise source signal s ( n ) is shown in FIG. 7C .

은 도 8a와 같다. By using the BW _Noise = 20 MHz bandwidth random noise source signal generated using the low-complexity bandwidth control noise signal generator 100, the desired frequency band is extended to a multi-band signal having an equal frequency interval of d = 50 MHz. The multi-band noise signal generated when the multi-noise signal generator 200 for generating a noise signal is applied to K = 1.

is shown in Figure 8a.

The two generated noise signals have similar frequency characteristics, and in order to improve this, the characteristics of two noise signals y ( n ) obtained by applying a convolution operation using a pseudo-random sequence are shown in FIG. 8B . 9 is a result showing noise signal characteristics when such signal processing is performed for K = 2, 3, and 4;

BW _Noise generated by using the low-complexity bandwidth-controlled noise signal generator 2100 = Noise that can be confirmed in the process of generating a multi-band noise signal with a desired non-uniform frequency interval using a random noise source signal having a bandwidth of 50 MHz The signal characteristics are as shown in FIGS. 10 and 11 .

의 전력 스펙트럼이다. 10A is a diagram illustrating a case in which a multi-band noise signal is generated at unequal frequency intervals using a random noise source signal having a bandwidth of 50 MHz, and a convolution operation with a pseudo-random sequence c ( n ) and a Hilbert transform are not applied. noise signal

is the power spectrum of

에 의사 랜덤 시퀀스 c(n)과의 컨볼루션 연산을 적용하지 않고 힐베르트 변환을 적용할 경우 도 10b와 같이 생성된 잡음 신호 사이에는 유사한 주파수 특성이 관찰되며, 의사 랜덤 시퀀스 c(n)과의 컨볼루션 연산 적용 후 힐베르트 변환을 적용할 경우 도 10c와 같이 다른 주파수 특성의 잡음 신호를 확인할 수 있다. 다중 잡음 신호를 기저대역으로 주파수 천이 시킬 경우 도 11b와 같은 전력 스펙트럼을 발생시킬 수 있다.multiple noise signal

When the Hilbert transform is applied without applying the convolution operation with the pseudo-random sequence c ( n ) to , similar frequency characteristics are observed between the generated noise signals as shown in FIG. When the Hilbert transform is applied after applying the solution operation, noise signals having different frequency characteristics can be identified as shown in FIG. 10C . When the multi-noise signal is frequency shifted to the baseband, a power spectrum as shown in FIG. 11B may be generated.

As can be seen from the analysis result, the apparatus for generating a multi-band noise signal according to the embodiment generates a noise source signal of a required bandwidth with low complexity and generates a desired number of noise signals in a desired frequency band using the generated noise source signal. It can be generated effectively, and it can be seen that the use value is high in the wireless environment including the defense field.

As shown in FIG. 12 , the first embodiment is a method for generating a noise signal performed in an apparatus for generating a noise signal, including generating a noise source signal sequence ( S100 ), and converting the noise source signal sequence into a specific frequency bandwidth. Converting to a controlled phase sample value sequence (S200), generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence (S300), and equalizing the noise source signal in the specific frequency band It may include generating a multi-noise signal by expanding the noise source signal of one frequency interval (S400), and randomizing and outputting the multi-noise signal (S500).

The generating of the noise source signal sequence ( S100 ) may be performed by a sequence generator of the noise signal generator.

The step of converting the noise source signal sequence into a phase sample value sequence controlled with a specific frequency bandwidth ( S200 ) may be performed by the phase sample value generator of the noise signal generator.

The step of generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence ( S300 ) may be performed by a numerically controlled oscillator of the noise signal generator.

The step ( S400 ) of generating a multi-noise signal by extending the noise source signal to a noise source signal having an equal frequency interval in the specific frequency band may be performed by the multi-noise signal generator.

The step of randomizing and outputting the multi-noise signal ( S500 ) may be performed by the randomizer.

As shown in FIG. 13 , the second embodiment is a noise signal generating method performed in a noise signal generating apparatus, including generating a noise source signal sequence ( S1100 ), and converting the noise source signal sequence into a specific frequency bandwidth. Converting to a controlled phase sample value sequence (S1200), generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence (S1300), and equalizing the noise source signal in the specific frequency band Generating a multi-noise signal by extending it to a noise source signal with a frequency interval that is not set (S1400), and randomizing and outputting the multi-noise signal (S1500); It may include extracting the signal (S1600).

The step of generating the noise source signal sequence ( S1100 ) may be performed by a sequence generator of the noise signal generator.

The step of converting the noise source signal sequence into a phase sample value sequence controlled with a specific frequency bandwidth ( S1200 ) may be performed by the phase sample value generator of the noise signal generator.

The step of generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence ( S1300 ) may be performed by a numerically controlled oscillator of the noise signal generator.

The step ( S1400 ) of generating a multi-noise signal by extending the noise source signal to a noise source signal having an uneven (non-uniform) frequency interval in the specific frequency band may be performed by the multi-noise signal generator.

The step of randomizing and outputting the multi-noise signal ( S1500 ) may be performed by the randomizer.

In the method for generating a noise signal according to an embodiment, the step of extracting the multiple noise signal having a positive frequency component from among the multiple noise signals ( S1600 ) may be performed by the Hilbert transform operation unit.

Various embodiments of this document are software (eg, a machine-readable storage media) (eg, a memory (internal memory or external memory)) including instructions stored in a readable storage medium (eg, a computer). : program) can be implemented. The device is a device capable of calling a command stored from a storage medium and operating according to the called command, and may include the electronic device according to the disclosed embodiments. When the command is executed by the control unit, the control unit may perform a function corresponding to the command directly or using other components under the control of the control unit. Instructions may include code generated or executed by a compiler or interpreter. The device-readable storage medium may be provided in the form of a non-transitory storage medium. Here, non-transitory means that the storage medium does not include a signal and is tangible, and does not distinguish that data is semi-permanently or temporarily stored in the storage medium.

According to the embodiment, the method according to the various embodiments disclosed in this document may be provided by being included in a computer program product.

According to one embodiment, there is provided a computer readable recording medium storing a computer program, comprising the steps of: generating a noise source signal sequence; converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence; and generating a multi-noise signal by expanding the noise source signal into a noise source signal having an equal frequency interval in the specific frequency band. and instructions for causing the processor to perform a method including an operation for performing the step of randomizing and outputting the multi-noise signal.

According to another embodiment, there is provided a computer readable recording medium storing a computer program, comprising the steps of: generating a noise source signal sequence, converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; , generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence, and generating a multi-noise signal by expanding the noise source signal to a noise source signal having unequal frequency intervals in the specific frequency band. A method comprising the steps of: randomizing and outputting the multi-noise signal; and extracting a multi-noise signal of a positive frequency component from among the randomized multi-noise signals. It may include a command to execute it.

According to one embodiment, there is provided a computer program stored on a computer-readable recording medium, comprising the steps of: generating a noise source signal sequence; converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence; and generating a multi-noise signal by expanding the noise source signal into a noise source signal having an equal frequency interval in the specific frequency band. and instructions for causing the processor to perform a method including an operation for performing the step of randomizing and outputting the multi-noise signal.

According to another embodiment, there is provided a computer program stored on a computer-readable recording medium, comprising the steps of: generating a noise source signal sequence; converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; , generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence, and generating a multi-noise signal by expanding the noise source signal to a noise source signal having unequal frequency intervals in the specific frequency band. A method comprising the steps of: randomizing and outputting the multi-noise signal; and extracting a multi-noise signal of a positive frequency component from among the randomized multi-noise signals. It may include a command to execute it.

Although the above has been described with reference to the drawings and embodiments, those skilled in the art will understand that various modifications and changes can be made to the embodiments without departing from the spirit of the embodiments described in the claims below. will be able

100, 2100: noise signal generator
200, 2200: multi-noise signal generator
300, 2300: randomization part
2400: Hilbert transform operator

Claims (15)

a noise signal generator generating a noise source signal of a specific frequency bandwidth;
a multi-noise signal generator for generating multi-noise signals of a plurality of frequency bands by expanding the noise source signal into a noise source signal having an equal frequency interval in the specific frequency band; and
and a randomizer configured to perform a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal. According to claim 1,
The noise signal generator,
a sequence generator for generating a noise source signal sequence;
a phase sample value generator that converts the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth; and
and a numerically controlled oscillator configured to generate a noise source signal of the specific frequency bandwidth based on the phase sample value sequence. 3. The method of claim 2,
wherein the sequence generator generates the noise source signal sequence using a random signal generator. 3. The method of claim 2,
and the phase sample value generator generates the phase sample value sequence by multiplying the noise source signal sequence by a bandwidth control value (BCV). 5. The method of claim 4,
The bandwidth control value BCV is determined by Equation (1).
[Equation 1]

(Where N _bit is the bit value, BW _Noise is the desired bandwidth, and fs is the sampling frequency) 3. The method of claim 2,
and the numerical control oscillator receives the phase sample value sequence, performs a phase accumulation operation, and generates a noise source signal of a specific frequency bandwidth through a modular operation of the calculated result. 7. The method according to any one of claims 1 to 6,
The multi-noise signal generator comprises: a bandwidth extension signal generator generating a bandwidth extension signal;
and a logic operation unit configured to generate a multi-noise signal in the specific frequency bandwidth by performing a logical product operation on the noise source signal and the bandwidth extension signal. delete a noise signal generator generating a noise source signal of a specific frequency bandwidth;
a multi-noise signal generator for generating multi-noise signals of a plurality of frequency bands by expanding the noise source signal into a noise source signal having non-uniform frequency intervals in the specific frequency band;
a randomizer for performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal; and
and a Hilbert transform calculating unit for extracting a multiple noise signal having a positive frequency component from among the multiple noise signals output from the randomization unit. A noise signal generating method performed in a noise signal generating apparatus, the method comprising:
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating a multi-noise signal of a plurality of frequency bands by expanding the noise source signal into a noise source signal having equal frequency intervals in the specific frequency band; and
and performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal. A noise signal generating method performed in a noise signal generating apparatus, the method comprising:
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating multiple noise signals of a plurality of frequency bands by expanding the noise source signal into a noise source signal having non-uniform frequency intervals in the specific frequency band;
performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal; and
and extracting a multi-noise signal of a positive frequency component from among the randomized and output multi-noise signals. As a computer-readable recording medium storing a computer program,
The computer program, when executed by a processor,
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating a multi-noise signal of a plurality of frequency bands by expanding the noise source signal into a noise source signal having equal frequency intervals in the specific frequency band; and
and instructions for causing the processor to perform an operation comprising performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal. As a computer-readable recording medium storing a computer program,
The computer program, when executed by a processor,
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating multiple noise signals of a plurality of frequency bands by expanding the noise source signal into a noise source signal having non-uniform frequency intervals in the specific frequency band;
performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal; and
and instructions for causing the processor to perform an operation including extracting a multi-noise signal of a positive frequency component from among the randomized and output multi-noise signals. As a computer program stored in a computer-readable recording medium,
The computer program, when executed by a processor,
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating a multi-noise signal of a plurality of frequency bands by expanding the noise source signal into a noise source signal having equal frequency intervals in the specific frequency band; and
and a computer program comprising instructions for causing the processor to perform an operation comprising performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal. As a computer program stored in a computer-readable recording medium,
The computer program, when executed by a processor,
generating a noise source signal sequence;
converting the noise source signal sequence into a controlled phase sample value sequence with a specific frequency bandwidth;
generating a noise source signal of a specific frequency bandwidth based on the phase sample value sequence;
generating multiple noise signals of a plurality of frequency bands by expanding the noise source signal into a noise source signal having non-uniform frequency intervals in the specific frequency band;
performing a convolution operation on the multi-noise signal and the pseudo-random sequence to randomize and output the multi-noise signal; and
A computer program comprising instructions for causing the processor to perform an operation including extracting a multi-noise signal of a positive frequency component from among the randomized and output multi-noise signals.

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