RU2108656C1 - Frequency multiplier - Google Patents

Abstract

FIELD: superhigh-frequency engineering. SUBSTANCE: frequency multiplier has cascaded input and output microstrip filters and varactor diodes connected in parallel to them. Output cavity of input filter also functions as input cavity of output filter, one or both of halves of its strip conductor are grounded through varactor diodes. First resonant frequency of output cavity of input filter equals input power frequency; second resonant frequency equals output power frequency. First resonant frequency of input filter input cavity equals input power frequency; third resonant frequency is higher than output power frequency; output power is supplied to it through voltage node as second resonant frequency. Second resonant frequency of output filter output cavity equals output power frequency; output power is taken off cavity in voltage node at input power frequency. First resonant frequency of output filter output cavity equals output power frequency. EFFECT: simplified design, improved accuracy. 4 cl, 1 dwg

Description

 The invention relates to techniques for microwave frequencies.

 A known frequency tripler [1], in which the input power is supplied to the vector diode through a coaxial input line, which protrudes through the side wall into the output waveguide. The triple-frequency currents generated by the diode excite propagating fields in the waveguide, one end of which is used as an output. At the other end of the waveguide there is a movable shorted piston for fine tuning the output. In this case, the cutoff frequency of the waveguide is higher than the fundamental frequency and the frequency of the second harmonic. Therefore, the waveguide is a high pass filter. A radial trap is located on the coaxial line. The trap forms a line break at a triple frequency, thereby preventing the triple frequency from entering the input. The position of this trap with respect to the diode is selected so as to adjust the diode reactance to the output frequency. The capacitance of the varactor diode and the inductance are selected so that the diode is tuned to a series resonance at the second harmonic, thereby closing the idle current. The disadvantage of the frequency accelerator [1] is its bulkiness and design complexity.

 The closest analogue is the frequency quadrupler [2], which contains a varactor diode, an automatic bias circuit, an input microstrip low-pass filter and an output microstrip bandpass filter.

 The disadvantage of the frequency quadrupler [2] is its bulkiness.

 The invention is aimed at reducing the number of elements of the frequency multiplier due to their more efficient use. The technical result of the invention is to reduce the frequency multiplier.

 The proposed frequency multiplier contains cascade-connected input and output microstrip filters and varactor diodes connected in parallel to them.

 The proposed frequency multiplier differs from the closest analogue in that the output resonator of the input filter is simultaneously the input resonator of the output filter, one or both halves of its strip conductor are shorted to ground through varactor diodes. The first resonant frequency of the output resonator of the input filter is equal to the frequency of the input power, and the second resonant frequency is equal to the output power.

 In addition, the first resonant frequency of the input resonator of the input filter is equal to the frequency of the input power, the third resonant frequency is located above the frequency of the output power, and the input power is supplied to it at the point of the voltage node at the frequency of the second resonance. The first resonant frequency of the output resonator of the output filter is equal to the frequency of the output power, or the second resonant frequency is equal to the frequency of the output power, and the output power is removed from the resonator at the point of the voltage node at the input power frequency.

 All these distinguishing features are aimed at obtaining a technical result.

 The drawing shows a diagram of a frequency multiplier made on three microstrip resonators.

 The frequency multiplier contains cascade-connected input and output microstrip filters and varactor diodes 1 connected in parallel to them. The output resonator 2 of the input filter is simultaneously the input resonator of the output filter. Both halves of its strip conductor are shorted to ground via varactor diodes 1. The first resonant frequency of the output resonator 2 is equal to the frequency of the input power, and the second resonant frequency is equal to the frequency of the output power.

 In addition, the first resonant frequency of the input resonator 3 of the input filter is equal to the frequency of the input power, the third resonant frequency is located above the frequency of the output power, and the input power is supplied to it at the point of the voltage node at the frequency of the second resonance.

 The second resonant frequency of the output resonator 4 of the output filter is equal to the frequency of the output power, and the output power is removed from the resonator at the point of the voltage node at the input power frequency, or the first resonant frequency of the output resonator 4 of the output filter is equal to the frequency of the output power.

 Depending on the type of varactor diode, the multiplier may have an automatic bias circuit, depending on the frequency bandwidth of the input and output power, at the input and output of the communication capacitance.

 The equality of the first resonant frequency of the resonator 3 to the input power frequency, of which the resonant frequency to the output power frequency is achieved by reducing the width of the Central part of the strip conductor [3].

 The frequency multiplier operates as follows.

 The input power, passing through the filter, enters its output resonator 2, loaded on a varactor diode 1. Varactor diode 1, being a nonlinear element, generates microwave oscillations at frequencies that are multiples of the frequency of the input power. Resonator 2 from all vibrations of multiple frequencies selects only those vibrations whose frequencies coincide with its resonant frequencies. There are two such frequencies: input power frequency and output power frequency. Oscillations at other multiple frequencies are suppressed by resonator 2. The output power passes through the output filter and goes to the frequency converters.

 The suppression of leakage of this power through the output filter is enhanced by the presence of a voltage node at the input of the input resonator 3. The suppression of the input power at the output of the multiplier is enhanced by the presence of a voltage node at the output of the output resonator 4 or the absence of resonant frequencies in the resonator 4 below the frequency of the output power.

 The conductive connection of the extreme resonator of the microstrip filter to the transmission line at the point of the voltage node is equivalent to introducing an additional notched quarter-wave loop into the microwave path.

Sources of information:
1. Microwave semiconductor devices and their application. Ed. G. Watson. - M .: Mir, 1972, p. 279.

 Design of microwave transmitting devices. Ed. G.M. Utkina. - M .: Owls. radio, 1979, p. 121.

Claims (4)

 1. A frequency multiplier comprising cascade-connected input and output microstrip filters, in which the output resonator of the input filter is simultaneously the input resonator of the output filter, varactor diodes connected to ground are connected to one or both ends, its first resonant frequency is equal to the input power frequency, characterized in that the second resonant frequency of the output resonator of the input filter is equal to the frequency of the output power.  2. The multiplier according to claim 1, characterized in that the first resonant frequency of the input resonator of the input filter is equal to the frequency of the input power, the third resonant frequency is higher than the frequency of the output power, and the input of the multiplier is located at the point of the voltage node at the frequency of the output power.  3. The multiplier according to claim 1, characterized in that the second resonant frequency of the output resonator of the output filter is equal to the frequency of the output power, and the output power is removed from the resonator at the point of the voltage node at the input power frequency.  4. The multiplier according to claim 1, characterized in that the first resonant frequency of the output resonator of the output filter is equal to the frequency of the output power.