RU2007106997A - METHOD FOR DEMODULATION OF AMPLITUDE-MODULATED RADIO FREQUENCY SIGNALS AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Claims (11)

1. The method of demodulating amplitude-modulated signals, which consists in the fact that the demodulator is turned on between a source of radio-frequency amplitude-modulated signals and a low-frequency load, and it is made from cascade-connected four-terminal, two-pole non-linear element, a low-pass filter, using the low-pass filter, information low-frequency signal, the amplitude of which varies according to the law of amplitude variation of the amplitude-modulated input signal, characterized in that the bipolar a linear element is connected between a source of radio-frequency amplitude-modulated signals and a four-terminal or between a four-terminal and a high-frequency load introduced into a longitudinal or transverse circuit, the four-terminal is made up of at least two resistive two-terminal, the parameter values of which are selected to provide the required amplitude modulation depth of the amplitude-modulated signal. 2. A device for demodulating amplitude-modulated signals, consisting of a cascade-connected four-terminal, two-pole non-linear element, a low-pass filter, a dividing capacitance and a low-frequency load connected in series, characterized in that the non-linear element is connected between the source of the amplitude-modulated signals and the four-terminal in a transverse circuit , a high-frequency load is connected to the output of the four-terminal, to which a low-pass filter is connected, the four-terminal is made of rubber tive-ports is not less than two, the values of which parameters selected to provide the desired value of the received amplitude modulation depth of the amplitude-modulated signal by using the following mathematical expression:

Where

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

m = m ₂₁ m _in ;

for m ₂₁ > 1 or

when m ₂₁ <1;

- the imaginary component of the conductivity of the signal source; m ₂₁ , m _I , m are the ratios of the transmission coefficient modules of the high-frequency part of the demodulator, the input signal and the signal at the high-frequency load in two states of the input signal, characterized by two extreme values of the amplitude of the amplitude-modulated signal; M ₂₁ , M _I , M - the depth of modulation of the transmission coefficient of the high-frequency part of the demodulator, the input signal and the signal at a high-frequency load; 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 the two extreme levels of the input amplitude-modulated signal; z _n = r _n + jx _n , z ₀ = r ₀ + jx ₀ - given complex resistance of the load and the signal source. 3. The device for the demodulation of amplitude-modulated 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, constituting a symmetrical closed T-joint selected 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; resistance r ₂ is selected from the condition of physical feasibility of the resistance r ₁ and r ₄ . 4. The device for the demodulation of amplitude-modulated 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 of the} two-terminal components of the L-shaped connection are selected using the following mathematical expression:

Where

D, E, F, r _n , x _n and the remaining notation have the same meaning as in clause 2. 5. The device for demodulating amplitude-modulated 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 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 the demodulation of amplitude-modulated 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 that make up a symmetrical T- shaped connection, selected using the following mathematical expressions:

Where

D, E, F, r _n , x _n and the remaining notation have the same meaning as in clause 2. 7. The device for demodulating amplitude-modulated 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, selected 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; the value of resistance r ₃ is selected from the condition of ensuring the physical feasibility of the resistance r ₁ , r ₂ . 8. The device for demodulating amplitude-modulated 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, selected 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 ₂ is selected from the condition of ensuring the physical feasibility of the resistance r ₁ , r _3. 9. The device for demodulating amplitude-modulated 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, constituting an asymmetric T-shaped connection, selected using the following magmatic expressions

Where

D, E, F, r _n , x _n and the remaining notation have the same meaning as in claim 2; the value of resistance r ₁ is selected from the condition of ensuring the physical feasibility of the resistance r ₂ , r ₃ . 10. The device for demodulating amplitude-modulated 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 components bridge connection, selected 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 demodulating amplitude-modulated 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 the U-shaped connection are selected using the following mathematical expression:

Where

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