RU2007103436A - METHOD FOR AMPLITUDE MODULATION AND PHASES OF RADIO-FREQUENCY SIGNALS AND DEVICES FOR ITS IMPLEMENTATION - Google Patents

Claims (11)

1. The method of modulating the amplitude and phase of the radio frequency signals, which consists in the fact that the modulator is made of a source of radio frequency signals, a four-terminal device, a controlled element connected to a source of a low-frequency control signal, a four-terminal device is made of two-terminal networks of at least two, the parameter values of which are selected from the condition providing the required amplitude-frequency and phase-frequency characteristics in two states of a bipolar controlled element, defined by two levels of low-frequency a control signal in a given frequency band, characterized in that the bipolar controlled element is connected between the signal source and the input of the four-terminal or between the output of the four-terminal and the load in the longitudinal or transverse circuit, to the output of the four-terminal connected load with complex conductivity for loop-through modulated RF signals, the conductivity of the signal source choose complex, all the two-terminal networks of the four-terminal network are resistive, the parameters of the resistive elements, the form bipole quadripole constituent selected from preset conditions ensure laws of change of amplitude and phase flow signal in a predetermined frequency band in two states managed bipolar element. 2. A device for modulating the amplitude and phase of radio frequency signals, consisting of a source of radio frequency signals, a bipolar controlled element, a four-terminal, made of the number of two-terminal, at least two, the parameter values of which are selected from the condition of providing the required amplitude-frequency and phase-frequency characteristics in two states of the controlled element connected to the source of the low-frequency control signal, characterized in that the four-terminal is made of resistive two-terminal, d a double-pole controlled element is connected between the source of the radio-frequency signals and the input of the resistive four-terminal into the transverse circuit, a load is connected to the output of the four-terminal, through-pass radio frequency signals with complex conductivities modulated in amplitude and phase, while the parameters of the resistive elements forming the resistive four-terminal are selected from the conditions for relations of modules (m) and phase differences (φ) of the transmission coefficient in two states of the controlled element, expressed by two extreme values of the low-frequency control signal, which are expressed in mathematical form in the following form: α = -γ (D + r _n ) + E; β = -Fγ + Dr _n , Where

;

;

; a, b, c, d - elements of the classical transmission matrix;

;

;

;

;

;

;

;

;

; y _1,2 = g _1,2 + jb _1,2 - set conductivity values of the controlled bipolar element in two states (1 and 2) defined by two extreme levels of the low-frequency control signal; z _n = r _n + jx _n , z _o = r _o + jx _o are the given complex resistances of the load and signal source; Δφ - a given value of the phase differences of the transmission coefficients, providing physical feasibility and the largest frequency band. 3. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of a symmetrical overlapped T-shaped connection of four resistive two-terminal, resistive r ₁ , r ₂ , r ₃ , r ₄ two-terminal components that make up the symmetrical overlapped T-shaped connection, selected from the condition of ensuring the required module ratios (m) and phase differences (φ) of the transmission coefficients in a given frequency band in two states of the controlled element using the following mathematics Sgiach expressions:

;

, Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2; resistance r ₂ is selected from the condition of physical feasibility of the resistance r ₁ and r ₄ . 4. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of a L-shaped connection of two resistive two-terminal, resistive r ₁ , r ₂ , two-terminal components making up the L-shaped connection are selected from the condition providing the required module ratios and phase differences of the transmission coefficients in a given frequency band in two states of the controlled element using the following mathematical expressions:

;

, Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2. 5. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form

-shaped connection of two resistive bipolar, resistive r ₁ , r ₂ bipolar components

-shaped connection, selected from the condition of ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

;

, Where

; D, E r _n , x _n and the remaining notation have the same meaning as in claim 2. 6. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of a symmetric T-shaped connection of three resistive two-terminal, resistive r ₁ , r ₂ , r ₃ = r ₁ two-terminal components of symmetrical T -shaped connection, selected from the condition of ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

;

, Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2. 7. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of an asymmetric T-shaped connection of three resistive two-terminal, resistive r ₁ , r ₂ , r ₃ two-terminal, making up an asymmetric T-shaped connection are selected from the conditions for ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

;

, Where

; D, E, r _n , x _n and the remaining notation have the same meaning as in claim 2; the value of resistance r ₃ is selected from the conditions for ensuring the physical feasibility of resistance r ₁ , r ₂ . 8. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of an asymmetric T-shaped connection of three resistive two-terminal, resistive r ₁ , r ₂ , r ₃ two-terminal, making up an asymmetric T-shaped connection are selected from the conditions for ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

; r ₃ = Qr _n -r ₂ , Where

; D, E, r _n , x _n and the remaining notation have the same meaning as in claim 2; the value of resistance r ₂ is selected from the conditions for ensuring the physical feasibility of resistance r ₁ , r ₃ . 9. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of an asymmetric T-shaped connection of three resistive two-terminal, resistive r ₁ , r ₂ , r ₃ two-terminal, making up an asymmetric T-shaped connection are selected from the conditions for ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

; r ₃ = Qr _n , Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2; the resistance value r ₁ is selected from the condition of ensuring the physical realizability of the resistance r ₂ , r ₃ . 10. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of a bridge circuit for connecting four resistive two-terminal, resistive r ₁ , r ₂ , r ₃ = r ₁ , r ₄ = r ₂ two-terminal constituting the bridge connection are selected from the condition of ensuring the required module ratios and phase differences of the transmission coefficients in a given frequency band in two states of the controlled element using the following mathematical expressions:

;

, Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2. 11. The device for modulating the amplitude and phase of the radio frequency signals according to claim 2, characterized in that the resistive four-terminal is made in the form of a symmetrical U-shaped connection of three resistive two-terminal, resistive r ₁ , r ₂ , r ₃ = r ₁ two-terminal components of P- shaped connection, selected from the condition of ensuring the required ratios of modules and phase differences of transmission coefficients in a given frequency band in two states of a controlled element using the following mathematical expressions:

;

, Where

; D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2.