RU2007108427A - METHOD FOR DEMODULATION OF PHASE-MODULATED RADIO-FREQUENCY SIGNALS AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Claims (6)

1. The method of demodulating phase-modulated signals, which consists in the fact that the demodulator is switched on between a source of radio-frequency phase-modulated signals and a low-frequency load and is made of a four-terminal device, a bipolar nonlinear element, a low-pass filter, a phase-modulated signal is converted into an amplitude-phase modulated signal, and the non-linear element is destroyed spectrum of the amplitude-phase-modulated signal for high-frequency and low-frequency components, using a low-pass filter, select a low-frequency information signal whose amplitude varies according to the law of phase change of the phase-modulated input signal, characterized in that the bipolar non-linear element is connected between the source of the radio-frequency phase-modulated signals and the four-terminal or between the four-terminal and the high-frequency load introduced into the longitudinal or transverse circuit, the four-terminal is made of resistive two-pole not less than three, the parameter values of which are selected from the condition for ensuring the required values amplitudes in two states and the amplitude modulation depth of the amplitude-phase-modulated signal, the phase-modulated signal is converted into the amplitude-phase-modulated signal by supplying this signal to the right slope of the frequency dependence of the complex resistance module of the nonlinear element, the low-frequency component of the amplitude-phase-modulated signal is fed to a differentiating circuit, or the conversion of the phase-modulated signal into an amplitude-phase-modulated signal is carried out by delivering this signal to the left slope of the dependence of the module of the complex resistance of the nonlinear element on the frequency, while the low-frequency component of the amplitude-phase modulated signal is fed to the integrating circuit, or the phase-modulated signal is converted into the amplitude-phase-modulated signal by applying this signal to the right slope of the dependence of the complex conductivity module of the nonlinear element of frequency, the low-frequency component of the amplitude-phase-modulated signal is fed to the integrating a circuit or the conversion of a phase-modulated signal to an amplitude-phase-modulated signal is carried out by supplying this signal to the left slope of the frequency dependence of the complex conductivity module of a nonlinear element, while the low-frequency component of the amplitude-phase-modulated signal is fed to a differentiating circuit. 2. A device for demodulating phase-modulated signals connected between a source of phase-modulated signals and a low-frequency load and consisting of a converter of phase-modulated signals into an amplitude-phase-modulated signal, a four-terminal, a two-pole nonlinear element, a low-pass filter, characterized in that the converter of the phase-modulated signals into an amplitude-phase-modulated signal is made in the form of a nonlinear element, the type of which is selected so that the left or right slopes of the dependency its complex conductivity versus frequency coincided with the frequency of the carrier oscillation of the phase-modulated signals, the non-linear element is connected between the phase-modulated signal source and the four-terminal in the transverse circuit, when choosing the left slope of the indicated dependence, the differentiating circuit is used as the low-frequency load, and when choosing the right slope, the integrating circuit, the four-terminal made from a number of resistive bipolar no less than three, the parameter values of which are selected from the conditions for ensuring the required s amplitude values in the two states, and the amplitude modulation depth of the amplitude-phase-modulated signal by using the following mathematical expression:

Where

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

for m ₂₁ > m ₂ or

when m ₁ <m ₂ ;

- the values of the transmission coefficient modules of the high-frequency part of the demodulator in two states of the input signal, characterized by two extreme values of the frequency of the phase-modulated signal; m _I - constant value of the input signal module;

- phase values of the input signal in its two states, characterized by two extreme frequency values of the phase-modulated signal; m ₂₁ , M ₂₁ is the ratio of the transmission coefficient modules of the high-frequency part of the demodulator in two states of the input signal and the amplitude modulation depth of the amplitude-phase modulated signal; y _1,2 = g _1,2 + jb _1,2 — set conductivity values of the controlled bipolar element in two states (1 and 2), determined by the two extreme frequency values of the input phase-modulated signal; z _{n1, n2} = r _{n1, n2} + jx _{n1, n2} , z _01.02 = r _01.02 + jx _01.02 are the specified complex resistances of the high-frequency load and the source of the phase-modulated signal in its two states. 3. The device for demodulating phase-modulated signals according to claim 2, characterized in that the resistive four-terminal is made in the form of two cascade-connected L-shaped connections of four resistive two-terminal, resistive r ₁ , r ₂ two-terminal, making up the first L-shaped connection, and resistive r ₃ , r ₄ bipolar, making up the second L-shaped connection, are selected using the following mathematical expressions:

where α, γ, and the remaining notation have the same meaning as in claim 2; the value of resistance r ₁ is selected from the conditions for ensuring the physical feasibility of the resistance r ₂ , r ₃ , r ₄ . 4. The device demodulation phase-modulated signals according to claim 2, characterized in that the resistive four-terminal is made in the form of two cascade-connected

-shaped connections of four resistive bipolar, resistive r ₁ , r ₂ bipolar, constituting the first

-shaped connection, and resistors r ₃ , r _{4 of the} two-terminal circuits that make up the second

-shaped connection, selected using the following mathematical expressions:

where α, β, γ, and the remaining notation have the same meaning as in claim 2; the value of resistance r ₄ is selected from the condition of ensuring the physical feasibility of the resistance r ₁ , r ₂ , r ₃ . 5. The device demodulation phase-modulated signals according to claim 2, characterized in that the resistive four-terminal is made in the form of two cascade-connected U-shaped connection of three resistive two-terminal and

-shaped connection of two resistive bipolar, resistive r ₁ , r ₂ , r ₃ , bipolar, making up the U-shaped connection, and resistive r ₄ , r ₅ bipolar, making up

-shaped connection, selected using the following mathematical expressions:

where α, γ, and the remaining notation have the same meaning as in claim 2; the values of the resistances r ₃ and r ₅ are selected from the conditions for ensuring the physical realizability of the resistances r ₁ , r ₂ , r ₄ . 6. The device for the demodulation of phase-modulated signals according to claim 2, characterized in that the resistive four-terminal is made in the form of an asymmetric blocked T-shaped connection of four resistive two-terminal, resistive r ₁ , r ₂ , r ₃ , r ₄ two-terminal components of the overlapped T-shaped compound selected using the following mathematical expressions:

Where

α, γ, and the remaining notation have the same meaning as in claim 2; the value of resistance r ₃ is selected from the condition of ensuring the physical feasibility of the resistance r ₁ , r ₂ , r ₄ .