RU2154340C2 - Device to compensate for noise in wide-band signal receivers - Google Patents

Abstract

FIELD: radio engineering, specifically, communication system with wide-band signals. SUBSTANCE: device has first multiplier, rejection filter and second multiplier connected in series, subtractor, third multiplier and output filter whose output is output of device. One of inputs of subtractor is connected to output of first adjustable delay element whose input is linked to input of first multiplier and is input of device. Output of generator of reference signal is simultaneously connected to another input of first multiplier and input of adjustable delay element. Output of the latter is connected at same time to inputs of second and third multipliers. EFFECT: increased noise immunity. 2 dwg

Description

 The invention relates to radio engineering and can be used in communication systems with broadband signals.

 Known interference compensation devices for receivers of broadband signals in a. with. N 1338078, CL. H 04 B 1/10, 1985, N 1698998 A1, Cl. H 04 B 1/10, 1991, the disadvantage of which is low noise immunity to narrow-band and structural interference.

 The closest in technical essence analogue to the invention is a device according to A.S. N 1688416 A1, Cl. H 04 B 1/10, 1991, which includes a first multiplier (phase shift key), a broadband reference signal generator, a second multiplier (phase remodulator), a notch filter, an output filter, a first attenuator, a subtractor, a first delay element, and a second delay element, band-pass filter, key, second attenuator, fourth delay element, narrow-band interference detector, third multiplier, third delay element, frequency channel.

 The device operates as follows. The input broadband phase-shifted signal and the noise are fed to the input of the first multiplier, where it is manipulated by the phase of the support with a broadband signal synchronous with the input broadband signal generated by the generator of the reference broadband signal. Due to this, the broadband signal is collapsed into a narrow-band signal, which is rejected by the notch filter, and the narrow-band noise is “smeared” into the broadband noise, which, through the notch filter that cuts the ΔF band from its spectrum, enters the second multiplier. In the second multiplier, the broadband interference is phase-locked by the synchronous reference broadband signal supplied to it from the output of the reference broadband signal generator through the first delay element, which ensures equalization of delays in the path of the broadband interference and the reference signal.

где Δf - полоса широкополосного сигнала, после чего подается на ключ, который открывается только в том случае, если обнаружителем принято решение об обнаружении помехи в данном парциальном канале. Помеха, прошедшая через ключ, через второй аттенюатор и четвертый элемент задержки поступает на один из входов вычитателя, где компенсирует помеху, поступающую на другой вход вычитателя с входа устройства через первый аттенюатор и второй элемент задержки. Второй и четвертый элементы задержки и первый и второй аттенюаторы обеспечивают выравнивание по амплитуде и времени помех, поступающих на разные входы вычитателя. Так как по одному входу вычитателя поступают широкополосный сигнал и узкополосная помеха, а по другим - только узкополосная помеха, то помехи компенсируются, а широкополосный сигнал проходит выход вычитателя. Широкополосный сигнал в третьем перемножителе "сворачивается" в узкополосный сигнал, который фильтруется в выходном фильтре, после чего поступает на выход устройства. Задержка третьего элемента задержки выбирается таким образом, чтобы обеспечить синхронность широкополосного сигнала и опорного сигнала на входах третьего перемножителя.Due to this procedure, the broadband interference is minimized to narrowband interference, which is fed to the N frequency channels. In each frequency channel, the narrow-band interference is filtered in the partial band of the band-pass filter equal to

where Δf is the band of the broadband signal, after which it is supplied to the key, which opens only if the detector decides to detect interference in this partial channel. The noise that passed through the key through the second attenuator and the fourth delay element is fed to one of the inputs of the subtractor, where it compensates for the noise coming to the other input of the subtractor from the input of the device through the first attenuator and the second delay element. The second and fourth delay elements and the first and second attenuators provide equalization in amplitude and time of the noise received at the different inputs of the subtractor. Since a broadband signal and a narrowband interference arrive at one input of the subtractor, and only a narrowband interference at the other, the interference is compensated, and the broadband signal passes the output of the subtractor. The broadband signal in the third multiplier is “folded” into a narrow-band signal, which is filtered in the output filter, and then fed to the output of the device. The delay of the third delay element is selected in such a way as to ensure the synchronization of the broadband signal and the reference signal at the inputs of the third multiplier.

раз по мощности за счет наличия широкополосной паразитной составляющей.The disadvantage of an analog is low noise immunity, because interference suppression cannot be achieved in more than

times in power due to the presence of a broadband spurious component.

 The technical result of the invention is to increase the noise immunity by suppressing the broadband spurious component.

 In the invention, the technical result is achieved due to the fact that in the interference cancellation device for a broadband signal receiver containing a first multiplier connected in series, the input of which is the input of the device, a notch filter and a second multiplier, a first subtractor, the other input of which is connected to the output of the first adjustable delay element , a reference broadband signal generator, the output of which is connected to another input of the first multiplier, and through the second adjustable delay element with the other input of the second multiplier, at the output of which a narrow-band interference component and a spurious wide-band interference component are formed, which pass to the second subtractor through a bandpass filter, a reference oscillator, a synchronous-phase filter, a first device with an adjustable transmission coefficient, a second device with an adjustable transmission coefficient and a third multiplier, the synchronous-phase filter being connected in series, the first device with an adjustable transfer coefficient, the second subtract l and the second device with an adjustable transmission coefficient, the output of which is connected to the input of the first subtractor, the output of which is the output of the device, the output of the reference generator through the third multiplier is connected to the reference input of the synchronous-phase filter, the signal input of which is connected to the output of the bandpass filter, the output of the second adjustable the delay element is connected to another input of the third multiplier, the input of the first adjustable delay element is connected to the input of the first multiplier.

 The block diagram of the device according to the invention is shown in FIG. 1, where the following notation is used: 1 and 3 - respectively, the first and second multipliers (phase manipulators); 2 - notch filter; 4 - second subtractor; 5 - the first subtractor; 6 - generator reference broadband signal (GSH); 7 - reference generator; 8 - the third multiplier (phase modulator); 9 - synchronous phase filter (SFF); 10 and 11, respectively, the first and second devices with adjustable transmission coefficient; 12 and 13, respectively, the first and second adjustable delay elements; 14 - band-pass filter.

 The device according to the invention comprises in series a first multiplier (phase shift key) 1, a notch filter 2, a second multiplier (phase shift key) 3, a band pass filter 14, a second subtractor 4, a second device with an adjustable gear ratio 11, a first subtractor 5, the output of which is the output the entire device, and the other input of the subtractor 5 is connected to the output of the first adjustable delay element 12, the input of which is connected to the input of the first multiplier (phase manipulator) 1 and is the input of the device a. The output of the reference broadband signal generator 6 is connected simultaneously with the other input of the first multiplier (phase manipulator) 1 and the input of the second adjustable delay element 13, the output of which is connected simultaneously with the other inputs of the second multiplier (phase manipulator) 3 and the third multiplier (phase modulator) 8. Output reference generator 7 through series-connected blocks 8, 9, 10 connected to block 4. Another input of the synchronous-phase filter 9 is connected to the connection point of blocks 14 and 4.

 The inventive device operates as follows.

The input broadband signal and interference are fed to the input of block 1, where they are phase-shifted to the [O, R] reference broadband signal (WPS) synchronous with the input broadband signal generated in the generator of the reference broadband signal 6. Due to this, the broadband signal is collapsed into a narrowband the signal that is rejected by the notch filter 2, and the narrow-band interference (UI) is “smeared” into a broadband noise, which through the notch filter 2 cuts out the ΔF band from it, where ΔF is the band of the minimized useful signal, p falls on the second multiplier 3. In the second multiplier 3, using the reference broadband signal coming from the GSh 6 through the second adjustable delay element 13, the broadband interference turns into a narrow-band interference. Along with the narrowband interference component at the output of the second multiplier 3, a spurious wideband interference component is generated due to the rejection of a part of the broadband interference power (generated at the output of the first multiplier 1) by notch filter 2. This interference component correlated with the useful broadband signal, has the same average frequency of the spectrum f ₀ and the same law of manipulation as the useful signal, and differs from it only in the initial phase. The narrowband and broadband components of the interference through the bandpass filter 14 are fed to the second subtractor 4, where the broadband component is subtracted from the mixture of narrowband and broadband components of the interference, which is formed as follows. The carrier frequency generated by the reference oscillator 7 is fed to the third multiplier 8, where it is phase-shifted by [O, P]. Formed SHPS is fed to the reference inputs of the synchronous-phase filter (SFF) 9, the signal inputs of which are fed a mixture of the narrow-band and broadband interference components from the output of the band-pass filter 14. The narrow-band interference component does not pass to the output of the SFF 9, because it is not in the reference signal, and the broadband component of the interference at the output of SFF 9 is similar to the broadband component at its signal input and differs from it only in the amplitude factor. Ensuring the equality of the amplitudes of the broadband interference components compensated in the second subtracter 4 is achieved by using the first device with an adjustable transmission coefficient 10. Thus at the output of the second subtractor 4, only the narrow-band interference component is extracted, which compensates for the interference in the input mixture in the first subtractor 5. Ensuring the equal amplitudes of the compensated narrow-band interference components is achieved by using a second device with an adjustable transmission coefficient 11. The first adjustable delay element 12 is used (if necessary ) to compensate for possible delays in the interference path. As a result of compensation UE at the output of block 5 is allocated only SHPS. The block diagram of the SFF 9 is shown in FIG. 2, where the following notation is used: 91, 93 - multipliers (balanced modulator), 92 - low-pass filter (low-pass filter), 95 - phase shifter 90 ^o , 94 - adder. These blocks are connected as shown in FIG. 3. SFF 9 works as follows. The signal from the output of the third multiplier 8, supplied to its reference input, is fed to the multipliers (balanced modulators) of the in-phase and quadrature channels of the multipliers 91 and 93. The voltage from the second multiplier 3 is supplied to the signal input of the SFF 9 (Fig. 2). In blocks 91 ₁ and 91 ₂ , the reference and signal voltages are multiplied, the multiplication result is filtered using the low-pass filter 92, after which the filter result is multiplied with the same reference signal.

 The common-mode and quadrature signal voltages are summed in the adder 94.

 In the device according to the invention, as well as in the closest analogue, at the output of the third multiplier 3, along with the narrowband interference component similar to the interference at the input of the device, a spurious wideband interference component is formed, correlated with the useful broadband signal. This component has a carrier frequency equal to the carrier of the useful broadband signal, and the same phase manipulation law, its difference from the useful signal is only in the initial phase of the high-frequency oscillation. In the device according to the invention, the spurious broadband interference component is compensated. Show it.

The reference inputs of the block SFF 9 is fed reference broadband signal of the form
U ₀ • cos [ω ₀ t + φ ₀ + φ (t)] (1)
where φ (t) takes the value [O, P] in accordance with the code used in the formation of the broadband signal generated by phase manipulation of the [O, P] harmonic signal generated by the reference oscillator 7 with the reference pseudorandom sequence of the output of the GSh 6 through the first subtractor 1.

раз, вида

.At the signal inputs of the SFF 9, a narrowband interference of the form
U _p • cos (ω _p t + φ _p )
and its broadband component, weakened in power in

times, kind

.

раз,

Т. о. , узкополосная составляющая помехи практически не проходит на выход СФФ.In the first multiplier 91 _{1, the} narrow-band interference is smeared into broadband due to multiplication with the reference broadband signal. The power of that part of the interference that falls into the low-pass filter 92 is attenuated in

time,

T. about. , the narrow-band component of the interference practically does not pass to the output of the SFF.

после повторного перемножения с тем же опорным широкополосным сигналом в третьем перемножителе 93₁ имеем

Аналогично, в квадратурном канале на выходе четвертого перемножителя 93₂ имеем

на выходе сумматора получаем

Из формулы (5) видим, что на выходе блока СФФ широкополосная составляющая помехи совпадает по частоте и фазе с широкополосной составляющей помехи на выходе блока 14 и отличается от нее только амплитудным множителем. Равенство амплитуд широкополосных составляющих помехи на входах вычитателя 4 обеспечивается за счет использования устройства с регулируемым коэффициентом передачи 10, который выполняется в виде резонансного усилителя с полосой пропускания Δf. T.o., в заявляемом устройстве обеспечивается возможность подавления паразитной широкополосной составляющей помех в n раз за счет ее компенсации, при этом коэффициент подавления ее на выходе устройства определяется как Б•n, где

база широкополосного сигнала. Поэтому степень подавления помех не зависит от базы ШПС.The result of the multiplication of the broadband signal and the broadband interference component at the output of the low-pass filter has the form

after repeated multiplication with the same reference broadband signal in the third multiplier 93 ₁ we have

Similarly, in the quadrature channel at the output of the fourth multiplier 93 ₂ we have

at the output of the adder we get

From formula (5), we see that at the output of the SFF block, the broadband component of the interference coincides in frequency and phase with the broadband component of the interference at the output of block 14 and differs from it only in the amplitude factor. The equality of the amplitudes of the broadband interference components at the inputs of the subtractor 4 is ensured by using a device with an adjustable transmission coefficient 10, which is performed in the form of a resonant amplifier with a passband Δf. To, in the inventive device, it is possible to suppress the parasitic broadband component of noise by a factor of n due to its compensation, while the coefficient of its suppression at the output of the device is defined as B • n, where

broadband base. Therefore, the degree of interference suppression does not depend on the base of the ShPS.

Claims (1)

 An interference compensation device for a broadband signal receiver, comprising a first multiplier connected in series, the input of which is the device input, a notch filter and a second multiplier, a first subtractor, the other input of which is connected to the output of the first adjustable delay element, a broadband reference signal generator, the output of which is connected to another the input of the first multiplier, and through the second adjustable delay element with the other input of the second multiplier, at the output of which the narrowband interference component and the spurious wideband interference component that pass through the bandpass filter to a second subtracter, characterized in that a reference oscillator, a synchronous-phase filter, a first device with an adjustable transmission coefficient, a second device with an adjustable transmission coefficient and a third multiplier are introduced, and in series a synchronous-phase filter, a first device with an adjustable transfer coefficient, a second subtractor and a second device with an adjustable coefficient are connected a transmission indent, the output of which is connected to the input of the first subtractor, the output of which is the output of the device, the output of the reference generator through the third multiplier is connected to the reference input of the synchronous-phase filter, the signal input of which is connected to the output of the bandpass filter, the output of the second adjustable delay element is connected to another input the third multiplier, the input of the first adjustable delay element is connected to the input of the first multiplier.

Images