RU1729262C - Device for compensation of intermodulation interference - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: device has first and second attenuators 1 and 2, first amplifier 3, subtracter 4, second amplifier 5, adder 6, third amplifier 7, delay gate 8, fourth amplifier 9, third attenuator 10, fifth amplifier 11, fourth attenuator 12. Intermodulation interference of order of two is suppressed by first and third amplifiers 3 and 7, if fourth and fifth amplifiers 9 and 11 are sign-inverting. The goal of invention is achieved by design of fourth and fifth amplifiers 9 and 11 which are sign-inverting identical, and which gain G equals to gain of first and third amplifiers 3 and 7. Attenuation ratio of first and fourth attenuators 1 and 12 is 1/G. EFFECT: decreased noise at output of device. 2 cl, 1 dwg

Description

 The invention relates to radio engineering and can be used in radio receivers for various purposes to protect against intermodulation interference (IP) arising in the input stages.

 Known devices for attenuating IP in amplifiers in which an additional amplification channel is provided with linearity different from the main channel. The out-of-phase addition of the channel output voltages makes it possible to compensate, under certain conditions, third-order IP At the same time, the second-order IP is only partially attenuated, which is a drawback of these devices.

, (1)
где А коэффициент передачи аттенюаторов.Of the known devices, the closest in technical essence to the proposed device is a device containing a first attenuator, the input of which is the input of the device, a second attenuator connected in series to the first amplifier, a subtractor, the input of which is subtracted is connected to the output of the second attenuator, the second amplifier and adder, the output of which is the output of the device, and connected in series with a third amplifier, the input of which is connected to the input of the device, and the output with the input of the second attenuator, and a delay element, the output of which is connected to another input of the adder, while the transmission coefficients of the attenuators are equal, and the gain of the second amplifier is determined by the expression
K = K

, (1)
where A is the attenuation coefficient of transmission.

 In the adder of this device is the addition of IP coming from the outputs of the second amplifier and the delay element. Due to the antiphase nature of these voltages and the equality of their amplitudes at the indicated optimal gain K of the second amplifier, third-order IP compensation occurs. For a second-order IP, this gain is not optimal. This causes only a partial compensation.

, (2) что совпадает с оптимальным значением по формуле (1), обеспечивающим подавление ИП третьего порядка. В результате в прототипе осуществляется полное подавление ИП третьего порядка и лишь частичное подавление ИП второго порядка. Наличие остатка нескомпенсированных ИП второго порядка является недостатком прототипа.Indeed, if U _{in.p is the} amplitude of two harmonic noise at the input, then a second-order IP at the output of the third amplifier is U _{7 (1,1)} = U _in.p2 , where α is the second-order intermodulation coefficient of the first and third amplifiers. At the output of the first attenuator, the interference amplitude is U _{1 (n)} = AU _in.p. Therefore, the output of the first amplifier of the second order U SP _{3 (1,1)} = α˙U _1P ² = α (AU _vh.p) ^2. At the output of the second attenuator, U _{2 (1,1)} = AU _{7 (1,1)} = A αU _input ² . In the subtractor, the difference U _{4 (1,1)} = U _{3 (1,1)} -U _{2 (1,1} ) = αA (1-A) U _terminal ^{2 is formed} . At the output of the second amplifier, U _{5 (1,1)} = KU _{4 (1,1)} = -K.˙αA (1-A) U _input ² . At the output of the prototype IP second-order U _{output (1,1)} = U _{8 (1,1)} + U _{5 (1,1} ) = α [1-KA (1-A)] U _input ² . Compensation requires that the expression in square brackets vanish. For this, the gain of the second amplifier should be determined by the expression
K = K

, (2) which coincides with the optimal value according to formula (1), which provides suppression of third-order IP. As a result, in the prototype, the third-order IP is completely suppressed and only the second-order IP is partially suppressed. The presence of the remainder of uncompensated second-order IP is a disadvantage of the prototype.

 The aim of the invention is to reduce the balance of uncompensated IP at the output of the device.

где А коэффициент передачи аттенюаторов, дополнительно введены последовательно соединенные четвертый усилитель и третий аттенюатор, включенные между выходом первого аттенюатора и входом первого усилителя, и последовательно соединенные пятый усилитель и четвертый аттенюатор, включенные между входом устройства и входом третьего усилителя, при этом четвертый и пятый усилители выполнены инвертирующими и идентичными с коэффициентами усиления G, равными коэффициентам усиления первого и третьего усилителей, а коэффициенты передачи третьего и четвертого аттенюаторов выбраны равным 1/G.This goal is achieved by the fact that in the known device containing the first attenuator, the input of which is the input of the device, the second attenuator, connected in series with the first amplifier, a subtractor, the input of which is subtracted is connected to the output of the second attenuator, the second amplifier and adder, the output of which is the output of the device, and connected in series with a third amplifier, the input of which is connected to the input of the device, and the output to the input of the second attenuator, while the transfer coefficients of the attenuators are equal, and the coefficient the gain of the second amplifier is determined by the expression
K = K

where A is the gain of the attenuators, a fourth amplifier and a third attenuator are connected in series, connected between the output of the first attenuator and the input of the first amplifier, and a fifth amplifier and fourth attenuator connected in series, connected between the device input and the input of the third amplifier, with the fourth and fifth amplifiers made inverting and identical with the gain G equal to the gain of the first and third amplifiers, and the transmission coefficients are third second and fourth attenuators chosen equal to 1 / G.

 The drawing shows a block diagram of an IP compensation device.

 The IP compensation device contains the first 1 and second 2 attenuators, the first amplifier 3, the subtractor 4, the second amplifier 5, the adder 6, the third amplifier 7, the delay element 8, the fourth amplifier 9, the third attenuator 10, the fifth amplifier 11, the fourth attenuator 12. Attenuators 1 and 2 have the same transmission coefficients. The gain of the amplifier 5 is determined by the gain of the attenuators in accordance with expression (1). The top input of the subtractor 4 is the input of the subtracted one, i.e. inverting input. Amplifiers 3 and 7 are identical and have the same gain. Amplifiers 9 and 11 are inverting and identical in characteristics to amplifiers 3 and 7 and have the same gain. Attenuators 10 and 12 have the same transmission coefficients equal to the reciprocal of the coefficient of amplifiers 3, 7, 9, 11.

 The device operates as follows.

Input interference with its frequencies (ω ₁ , ω ₂ ) and the initial phases (φ ₁ , φ ₂ ) branch and enter the input of the inverting amplifier 11 and through the attenuator 1 to the input of the inverting amplifier 9. In the amplifiers, this interference is amplified, accompanied by inversion of the initial phases φ ₁ + π, φ ₂ + π. In addition, in the amplifiers there is the formation of second-order IP (with frequency ω ₁ + ω ₂ and phase φ ₁ + φ ₂ + π) and third-order (with frequency 2ω ₁ - ω ₂ and phase 2φ ₁ - φ ₂ + π), also accompanied by phase inversion. In attenuators 12 and 10, all these products are weakened. In amplifiers 7 and 3, amplification of second-order and third-order IPs formed in amplifiers 11 and 9 occurs without phase change if these amplifiers are non-inverting (φ ₁ + π, φ ₂ + π, 2φ ₁ -φ ₂ + π), or phase inversion, if amplifiers 7 and 3 are inverting (φ ₁ + φ ₂ + 2π, 2φ ₁ - φ ₂ + 2π). In addition, in amplifiers 7 and 3 from interference (at frequencies ω ₁ and ω ₂ ), second-order and third-order IP are again formed without phase inversion, if amplifiers 7 and 3 are non-inverting ([φ ₁ + π) + (φ ₂ + π )] φ ₁ + φ ₂ + π [2x (φ ₁ + π)) - (φ ₂ + π)] 2 φ ₁ --φ ₂ + π), or with phase inversion if amplifiers 7 and 3 are inverting ([ (φ ₁ + π) + + (φ ₂ + π) + π] φ ₁ + φ ₂ +3 π. [2 (φ ₁ + π) - - (φ ₂ + π) + = 2 φ ₁ - φ ₂ + 2π)] In any case, with inverting amplifiers 9, 11, second-order SPs at the outputs of amplifiers 3, 7 are formed from two antiphase components. At a certain value of the transfer coefficient of the attenuators 12 and 10, the amplitudes of these components are equal and, as a result, their mutual compensation. Due to this, there is no second-order IP at the outputs of amplifiers 3 and 7. Third-order IPs at the outputs of amplifiers 3 and 7 are formed from two in-phase components. The result is a summation of these components. In this case, the level of third-order IP at the output of amplifier 3, i.e. at the non-inverting input of subtractor 4, less than at the output of attenuator 2, i.e. at the inverting input of the subtractor 4. This is because the attenuator 1, included in front of the amplifier 9, weakens the third-order PI in proportion to the third degree of its transfer coefficient, and the attenuator 2, included after the amplifier 7, gives attenuation proportional to the first degree. With regard to the useful signal, the attenuators 1 and 2 are absolutely equivalent and produce the same attenuation proportional to the first degree of the transmission coefficient, therefore, the levels of the useful signal at the inputs of the subtractor 4 are the same. Therefore, the output voltage of the subtractor 4 does not contain a useful signal and interference (at frequencies ω ₁ and ω ₂ ) and is equal to the difference of the third-order IP coming from the outputs of the amplifier 3 and attenuator 2. Moreover, the phase of this product is opposite to the third-order IP phase at the output of the amplifier 7 , the amplitude is less than the amplitude of the SP at the output of the amplifier 7. Amplifier 5 with a certain ratio between its gain and gain of the attenuators [see expression (1)] raises the IS level to the IS level at the output of the delay element 8, which is turned on to preserve the antiphase of the third-order IP at the inputs of the adder 6. As a result, the third-order IP is compensated in the adder and the output voltage contains only the useful signal input the adder from the output of the amplifier 7 through the delay element 8.

 We find the transfer coefficient of the attenuators 12 and 10, which provides suppression of second-order IP.

Let U _{in.p be the} amplitude of two harmonic noise at the input of the device. Second-order IP at the amplifier output 11 U _{11 (1,1)} = αU _input ² , where α is the second-order intermodulation coefficient, and at the output of the amplifier 9 U _{9 (1,1)} = α (AU _input ) ² , where A is the gain of the attenuators 1 and 2. The amplitudes of harmonic interference at the outputs of the amplifiers 11 and 9 are respectively U _{11 (p)} = GU _Ip and U _{9 (p)} = GAU _Ip , where G is the gain of the amplifiers. After attenuators 12 and 10, second-order _SPs have the levels U _{12 (1,1)} = BU _{11 (1,1)} = B α U _input ² , U _{10 (1,1)} = BU _{9 (1,1)} = B α (AU _int.p. ) ² , where V is the attenuation coefficient of the attenuators 12, 10. The amplitudes of harmonic interference are U _{12 (p)} = BU _{11 (p)} = BGU _int.p and U _{10 (p)} = BU _{9 ( n)} = BGAU _input From these interferences, amplifiers 7 and 3 again form second-order IPs with the levels U ' _{7 (1,1)} = αU ² _{12 (n)} = (ВGU _input ) ² and U' _{3 (1,1)} = αU _{10 (n)} ² = α (BGAU _input ) ² . In addition, amplifiers 1 and 3 are amplified by second-order PIs previously formed in amplifiers 11 and 9. These components have levels U ₇ ¹¹ _(1,1) = GU _{12 (1,1)} = GB α U _input ² and U ₃ ¹¹ _(1,1) = GU _{10 (1,1)} = GB αU _int.p ) ² . Given the antiphase nature of these components of the IP of this order at the output of the amplifier 7U _{7 (1,1)} = U _{7 (1,1)} ¹ -U '' _{g (1,1)} = αGB (BG-1) U _input ² . Similarly, at the output of the amplifier 3U _{3 (1,1)} = U _{3 (1,1)} ¹ -U _{3 (1,1)} ¹¹ = αGB (BG-1) (AU _input ) ² . To compensate for a second-order IE, it is necessary that the expression in parentheses vanish. Hence the optimum transfer coefficient of the attenuators 12, 10 V = 1 / G.

. (Минимальный К=2,6 достигается при А=0,57).As for the third-order IP, taking into account the in-phase of the components, they have 7 U _{7 (2,1)} = U _{7 (2,1)} ¹ + U _{7 (2,1)} ¹¹ = βGB (BG + 1) U _{in .p} ³ , and at the output of the amplifier 3 U _{3 (2,1)} = U _{3 (2,1)} ¹ + U _{3 (2,1)} ¹¹ = βGB (BG + 1) (AU _input ) ³ , where β- third-order intermodulation coefficient. At the output of the attenuator, 2 U _{2 (2,1)} = AU _{7 (2,1)} = Aβ GB (BG + 1) U _input ³ . In subtracter 4, the difference U _{4 (2,1)} = U _{3 (2,1)} -U _{2 (2,1)} = βGB (BG + 1) A (A ² -1) U _input ^{3 is formed} . After the amplifier, 5 U _{5 (2,1)} = KU _{4 (2,1)} = -K βGB (BG + 1) A (1-A ² ) U _input ³ . At the output of the device, U _{out (2.1)} = U _{7 (2.1)} + + U _{5 (2.1)} = U _{8 (2.1)} + U _{5 (2.1)} = βGB (BG + 1) [1-KA (1-A ² )] U _terminal ³ . Third-order IP compensation occurs when the expression in square brackets vanishes. Hence the optimal gain of amplifier 5, as well as the prototype K = K

. (Minimum K = 2.6 is achieved at A = 0.57).

 The use of new elements identical inverting the fourth and fifth amplifiers, identical in characteristics to the first and second amplifiers, as well as the third and fourth attenuators, the transmission coefficient of which is in a certain way related to the gain of these amplifiers, compares the proposed device from the prototype. Thanks to these elements, the balance of uncompensated second-order IEs is reduced. As a result, the device simultaneously, without reconfiguration, effectively suppresses second and third order IP. The device is convenient for practical implementation, since identical standard amplifiers are used as amplifiers 3, 7, 9, 11.

Claims (1)

INTERMODULATION INTERFERENCE COMPENSATION DEVICE, comprising a first attenuator, the input of which is the input of the device, a second attenuator connected in series to the first amplifier, a subtractor, the input of which is subtracted is connected to the output of the second attenuator, a second amplifier and adder, the output of which is the output of the device, and a third amplifier connected in series whose output is connected to the input of the second attenuator, and a delay element, the output of which is connected to another input of the adder, while the coefficients The first and second attenuators are equal, and the gain K of the second amplifier is determined by the expression

where A is the gain of the attenuators,
characterized in that, in order to reduce the balance of uncompensated intermodulation interference at the output of the device, a fourth amplifier and a third attenuator are connected in series, connected between the output of the first attenuator and the input of the first amplifier, and a fifth amplifier and fourth attenuator are connected in series, connected between the device input and the input of the third amplifier, while the fourth and fifth amplifiers are inverting and identical with the gain G equal to the gain Lenia first and third amplifiers, and the transmission coefficients of the third and fourth attenuators chosen equal to 1 / G.