RU2010118287A - METHOD FOR GENERATING HIGH FREQUENCY SIGNALS AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Abstract

 1. A method of generating high-frequency signals based on the conversion of the energy of a constant voltage source into the energy of a high-frequency signal, the interaction of a high-frequency signal with a direct transmission circuit and a feedback circuit, constructing a direct transmission circuit in the form of a three-pole nonlinear element connected to its output electrode of the first reactive four-terminal device, the output of which is connected to the load, the organization of external feedback in the form of a second reactive four-terminal with connected to its input the output and output, respectively, of the first and second two-terminal with complex resistances, the connection of the first two-terminal with complex resistance with a load in the transverse circuit, the fulfillment of the excitation conditions in the form of a balance of amplitudes and phase balance, which respectively determine the amplitude and frequency of the generated high-frequency signals, matching conditions of the output electrode of a three-pole nonlinear element with a load and conditions for matching the load with the control electrode of a three-pole nonlinear element, distinguishing In that the load is selected in the form of an arbitrary resistance, a third two-terminal with complex resistance is connected to the transverse circuit in front of the control electrode of the three-pole nonlinear element, a second two-terminal with complex resistance is connected to the third two-terminal with complex resistance in the transverse circuit, the matching conditions are realized by choosing the frequency characteristics of the first and second four-terminal networks from the condition of providing a stationary generation mode at the back

Claims (2)

1. A method of generating high-frequency signals based on the conversion of the energy of a constant voltage source into the energy of a high-frequency signal, the interaction of a high-frequency signal with a direct transmission circuit and a feedback circuit, constructing a direct transmission circuit in the form of a three-pole nonlinear element connected to its output electrode of the first reactive four-terminal device, the output of which is connected to the load, the organization of external feedback in the form of a second reactive four-terminal with connected to its input the output and output, respectively, of the first and second two-terminal with complex resistances, the connection of the first two-terminal with complex resistance with a load in the transverse circuit, the fulfillment of the excitation conditions in the form of a balance of amplitudes and phase balance, which respectively determine the amplitude and frequency of the generated high-frequency signals, matching conditions of the output electrode of a three-pole nonlinear element with a load and conditions for matching the load with the control electrode of a three-pole nonlinear element, distinguishing In that the load is selected in the form of an arbitrary resistance, a third two-terminal with complex resistance is connected to the transverse circuit in front of the control electrode of the three-pole nonlinear element, a second two-terminal with complex resistance is connected to the third two-terminal with complex resistance in the transverse circuit, the matching conditions are realized by selecting the frequency characteristics of the first and second four-terminal networks from the condition of providing a stationary generation mode at the rear a given number of frequencies in the form of the implementation of the set values of the modules and phases of the transmission coefficients of the direct transmission circuit, the values of the modules of transmission coefficients of the feedback circuit inversely proportional to the values of the modules of transmission coefficients of the direct transmission circuit and the values of their phases - opposite and equal in absolute value at all given frequencies at the specified amplitude of the DC voltage on a three-pole nonlinear element in accordance with the following mathematical expressions:

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, Where

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; A ₁ = -xsin (φ ₁ ) + rcos (φ ₁ ); B ₁ = x ₁₁₀ cos (φ ₁ ) + r ₁₁₀ sin (φ ₁ ); C ₁ = r ₁₁₀ cos (φ ₁ ) -x ₁₁₀ sin (φ ₁ ); H ₁ = xcos (φ ₁ ) + rsin (φ ₁ );

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- optimal frequency dependences of the corresponding elements of the resistance matrices of the first (I) and second (II) four-terminal networks;

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- given frequency dependencies of the corresponding elements of the resistance matrices of the first and second four-terminal networks; m ₁ and φ ₁ are the given frequency dependences of the modules and phases of the transfer function of the direct transmission circuit; m ₂ and φ ₂ are the optimal frequency dependences of the modules and phases of the transfer function of the feedback circuit; r ₀ , x ₀ - given frequency dependences of the real and imaginary components of the resistance of the first and third two-terminal with complex resistances; r _n , x _n - given frequency dependences of the real and imaginary components of the load resistance and the second two-terminal with complex resistance;

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- given dependences of the real and imaginary component elements of the resistance matrix of a three-pole nonlinear element on the frequency of the generated high-frequency signals at a given amplitude of the constant voltage. 2. A device for generating high-frequency signals, consisting of a constant voltage source, a direct transmission circuit in the form of a three-pole nonlinear element, to the output electrode of which a first reactive four-terminal device is connected, to the output of which a load is connected to the transverse circuit, and external feedback circuits in the form of a second reactive four-terminal device with connected in transverse circuits to its input and output, respectively, by the first and second two-terminal with complex resistances, the first two-terminal with complex resistors parallel to the load, characterized in that the load is selected in the form of an arbitrary complex resistance, a third two-terminal with complex resistance is connected to the second two-terminal with complex resistance in a transverse circuit, connected on the other hand to the control electrode of the three-pole nonlinear element, the first and second reactive four-terminal made in the form of a U-shaped connection of three reactive bipolar, moreover, the numbering of reactive bipolar in the first four yusnike starts from the output electrode tripolar nonlinear element, and the second quadrupole numbering reactive two-terminal starts from the first two-terminal network with a complex impedance, wherein the second and third reactive two-pole two-ports are made in the form of two parallel-connected series circuit of elements with parameters L _1k, C _1k , Z _2k , C _2k , the values of which are determined in accordance with the following mathematical expressions:

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, Where

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; x = a ₂ c ₁ - a ₁ c ₂ ; y = a ₂ d ₁ + b ₂ c ₁ - a ₁ d ₂ -b ₁ c ₂ ; z = b ₂ d ₁ -b ₁ d ₂ ;

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; A ₁ = -xsin (φ _1n ) + rcos (φ _1n ); B ₁ = x ₁₁₀ cos (φ _1n ) + r ₁₁₀ sin (φ _1n ); C ₁ = r ₁₁₀ cos (φ _1n ) -x ₁₁₀ sin (φ _1n ); H ₁ = xcos (φ _1n ) + rsin (φ _1n );

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- the optimal values of the resistances of the second and third reactive two-terminal networks of the first (I) and second (II) four-terminal networks at given four frequencies ω _n = 2πf _n ; n = 1, 2, 3, 4 - frequency number;

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- set resistance values of the first reactive two-terminal of the first (I) and second (II) four-terminal at given four frequencies; m _1n and φ _1n are the specified values of the modules and phases of the transfer function of the direct transmission circuit at given four frequencies; m _2n and φ _2n are the optimal values of the modules and phases of the transfer function of the feedback circuit at given four frequencies; r _0n , x _0n are the given values of the real and imaginary components of the resistance of the first and third two-terminal devices with complex resistances at the given four frequencies; r _nn , x _nn - set values of the real and imaginary components of the load resistance and the second two-terminal with complex resistance at the given four frequencies;

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- given values of the real and imaginary components of the resistance matrix of a three-pole nonlinear element at the specified four frequencies of the generated high-frequency signals at a given amplitude of the constant voltage; k = 2, 3 - the number of the two-terminal U-shaped connection of three reactive two-terminal systems of the first and second reactive four-terminal networks in the above numbering order.