SU892351A1 - Device for measuring tuned circuit quality factor - Google Patents

Description

(54) DEVICE FOR MEASUREMENT OF VIBILITY OF VIBRATING CIRCUITS

Claims (2)

The invention relates to the field of radio measuring equipment and can be used to measure the quality factor, loss tangent, resistance, capacitance and inductance of radio elements of the oscillating circuits. A device for measuring the quality factor, inductance and capacitance in digital form is known, which contains a signal source, an oscillating circuit, a voltage ratio unit, an amplitude maintenance unit, a wideband amplifier covered by feedback through an exemplary reactive element, and automatic gain and phase adjustment units 1 . A disadvantage of the known device is the limited range of inductance and capacitance measurement frequencies in a digital form, and the measurement of voltages proportional to the quality factor of an oscillating circuit is made with relatively large errors. The closest technical solution to the proposed device is a device for measuring the quality factor of oscillating circuits containing tunable high frequency generator, frequency modulator, oscillating circuit, amplitude detector, resonant search unit H simplicity, comprising a unit separating the first derivative of the frequency and nulorgan block release of the second derivative of the frequency nulorgan additional two memory blocks, low frequency tunable oscillator, a key block frequency ratio and a control unit 2.. The known device does not provide a reference of the capacitance of the oscillating circuit in a digital form and does not allow to estimate the value of the capacitance at the measurement frequency. The aim of the invention is an extension. rhenium device functionality. The goal is achieved by the device for measuring the quality factor of the oscillating circuits, containing a tunable high-frequency generator, one output of which is connected to the first input of the frequency modulator, the second input of which is connected to the output of the key, and the output of the frequency modulator is connected to the input of the frequency modulator an amplitude detector, the output of which is connected to the input of the resonant frequency search block, one output of the latter is connected to the input of the extraction block of the second frequency derivative, and the other the output is connected to the input of the first storage unit, the output of which is connected to the input of a tunable high-frequency generator, the input of the key is connected to one of the inputs of the frequency ratio block and to the output of a tunable low-frequency generator whose input is connected to the output of the second storage unit, the input of the latter is connected to a null organ output, control inputs of the key, the first and second memory blocks, the frequency modulator, the resonant frequency search block and the second frequency derivative selection block, respectively Three additional switches and a chain of two series-connected capacitors and a frequency divider are entered, directly connected to the outputs of the control unit, and the output of the tunable high-frequency generator is connected via series-connected first additional switch, the other input of which is connected to the input of the frequency modulator and the frequency divider to the input frequency ratio block, and the first output of the second auxiliary key is connected to the input of the null organ, the second and third outputs are respectively connected to the input ohm and the output of the second frequency derivative block, and a circuit of two series-connected capacitors is connected between the amplitude detector input and a common bus, and the common output of a circuit of two series-connected capacitors is connected via a third additional key to a common bus, whose control input is respectively connected with the output of the control unit. FIG. 1 shows the functional electrical circuit of the device; at 51. 4 of FIG. 2 are diagrams explaining the operation of the device. The device contains a frequency modulator 1, to one input of which is connected the output of a tunable high-frequency generator 2, and to the second input via key 3 the output of a tunable low-frequency generator, oscillating circuit 5, the input connected to the output of frequency modulator 1 and the output to the amplitude input the detector 6, the output of which is connected to the input of the resonance frequency search unit 7, containing the first 8 frequency derivative extraction unit 8 sequentially connected and the zero-organ 9 storage unit 10, is connected by the input Connected to the output of the resonant frequency search unit 7 and the output to the control input of the tunable high frequency generator 2; block 11 for allocating the second derivative in frequency, the input connected to the output of block 8 for allocating the first derivative in frequency, key 12, one input connected to the output of block 11 for allocating the second derivative in frequency and the second input to the output of block 8 for allocating the first derivative for frequency, zero -organ 13, the input connected to the output of the key 12, the second storage unit 14, the input connected to the output of the null organ 13 and the output to the tunable low-frequency generator k; two successively connected capacitors 15 and 16 connected between the output of the coupling circuit 5 and the common bus, an additional switch 17 connected between the connection point of the capacitors 15 and 16 and the common bus, frequency ratio unit 18, the first input connected to the output of the tunable low frequency generator C, divider 4actoTbr 19, the input connected via an additional switch 20 to the output of a tunable high-frequency generator 2 and to the output of a frequency modulator 1, control unit 21 connected to the control inputs of the search unit 7 ka resonance frequency, a second frequency derivative allocation unit 11, a frequency modulator 1, storage units 10 and H, and keys 3 and 17. The quality factor is measured as follows. The frequency divider 19 is switched to division mode 2 and its input is connected via an additional switch 20 to the output of the high-frequency generator 2, the input of the null organ 13 is connected via the switch 12 to the output of the allocation unit 11 of the second frequency derivative, the additional switch 17 is opened. In the resonant frequency search mode, the control unit 21 opens the storage unit 10 for a specified time, closes the second storage unit 14 and the key 3, and translates the frequency modulator 1 in. high frequency carrier selection mode. During this time, the search resonance frequency unit 7 produces a linearly time-varying voltage Uc (Fig. 2c). This voltage changes the frequency of the output voltage of a tunable high-frequency generator 2, which through frequency modulator 1 enters the input of the oscillating circuit 5. After passing through the oscillating KOHTvp 5 and the amplitude detector 6, the high-frequency voltage with a varying frequency is converted into a voltage Uq, time-varying (Fig. 2a) and corresponding to the amplitude-frequency characteristic of the oscillating circuit under study 5. This time-varying voltage is the unit 8 for extracting the first derivative a frequency controlled by the control unit 21 differentiates, whereby its output is isolated from the voltage Ug (FIG. 26), proportional to the first derivative of chastoTe of amplitude-frequency characteristics of the oscillation circuit 5, ie. nor “jr, where a is a constant coefficient of proportionality. This voltage is controlled by a nullorgan 9. in which, when the voltage U passes through zero, the output is set. the voltage and, (Fig. 2c) and therefore, the frequency of the output voltage of the tunable high-frequency oscillator 2 is set equal to its own resonant frequency of the oscillating circuit 5. In the skip band selection mode, the control unit 21 closes the second memory for a specified time block 14 and key 3 and switches frequency modulator 1 to the side frequency selection mode. At this time, in the storage unit 10, the voltage Ulo / Yv 1FIG is memorized. 2c) and, consequently, the frequency of the output voltage of the high frequency generator to be deconstructed 2, is equal to its own resonant frequency of the oscillating circuit 5. At the same time, the zero-body 13 produces a voltage that varies linearly with time (Fig. 2e). the voltage changes the frequency of the output voltage of the tunable low frequency generator 4, which through the key 3 goes to the second input of the frequency modulator 1. As a result, two voltages are applied to the frequency modulator 1 with frequencies f and F, tense with a frequency fo f ± P. where fg-frequency tunable generator 2 high frequency; F - frequency tunable oscillator 4 low frequency. After passing this voltage through the oscillating circuit 5, the amplitude detector 6 and the extraction unit 8 of the first frequency derivative, the high-frequency voltage with a varying frequency f is converted to a voltage. 26} f the time-varying and corresponding to the first derivative of software with the amplitude-frequency characteristic of the oscillating circuit 5. This voltage is the block 11 for selecting the second derivative of the oscillator circuit 5, controlled by the control unit 21, differentiates, in as a result, the voltage U (Fig. 2e) I is proportional to the second derivative with respect to the frequency of the amplitude-frequency characteristic of the oscillating circuit 5, i.e. .., Lee ZTg where b is a constant coefficient of proportionality. This voltage is controlled by an additional null-organ 13, in which, when the voltage Uj passes through zero, the output voltage i is established, fig. 2e) is fixed in the second storage unit H, and therefore, the frequency of the output voltage of the tunable low frequency generator is fixed, equal to half the bandwidth of the oscillating circuit 5 between the inflection points of its amplitude-frequency characteristic. The transition from the resonant frequency search mode to the bandwidth allocation mode is performed automatically by the control unit 21 at predetermined time intervals. At the same time, the quality factor is determined by the shape, for f., T "-, fo Q 0.707, and is directly measured by the ratio block 18, which also measures the target operating frequency at which the quality measurement is made. The measurement of the capacitance of the measuring circuit 5 at the resonant frequency is carried out as follows. The frequency divider 19 is switched to division mode and its input is connected via an additional switch 20 to the output of frequency modulator 1, the input of the null organ 13 is connected via an additional switch 12 to the output of the extraction unit 8 of the first frequency derivative, additional switch 17 is transferred to controlled mode. The control unit 21 opens the storage unit 10 for a specified time. closes the second storage unit 1, the keys 3 and the additional key 17, and switches the frequency modulator 1 to the high frequency carrier selection mode. During this time, the frequency of the tunable high-frequency oscillator is searched for, corresponding to its own resonant frequency of the oscillating circuit 5, as described in the search mode of the resonant frequency. After a predetermined time sufficient to adjust the tunable high-frequency generator 2 to its own resonant frequency of the oscillatory circuit 5, the control unit 21 closes the storage unit 10 for a specified time, opens the second storage unit and key 3 and additional key 17, and converts the frequency modulator 1 to side frequency selection mode. At this time, remember the frequency, fo, of the output voltage of the tunable high-frequency oscillator 2, is equal to its own 1. 8 to the resonant frequency of the oscillating circuit 5. The open additional switch 17 short circuits the capacitor 16, and therefore changes the values of the capacitance and the natural resonant frequency of the oscillating circuit 5, respectively, to the values of Dc and Af. At this time, the null organ 13, under the control of the extraction unit 8, of the first derivative in frequency, begins to produce a voltage linearly varying with time. This voltage changes the frequency of the output voltage of the tunable low-frequency oscillator, which through switch 3 enters the second input of frequency modulator 1. As a result, the output of frequency modulator 1 produces voltage with frequency ff о - F. When frequency f reaches equal to the natural resonant frequency of the oscillating circuit 5. The frequency F of the tunable low frequency generator k is fixed by the null member 13, as described in the passband search mode. The capacitance of the oscillating circuit 8 is measured when the control unit 21 periodically switches the device from the search mode of the resonant frequency to the detuning mode of the oscillating circuit 5. At the same time, the capacitance of the oscillating circuit 5 is determined by the formula VVg-LS, (1) where -F is the natural resonance frequency of the oscillating circuit 5 in Fit when its capacitance value changes by dc; F uf is the value of the detuning of the natural resonant frequency of the oscillating circuit 8 in Fq. when the value of its capacitance changes by d s. If you select capacitance values of capacitors 15 and 1b small, at which condition 0.05 is fulfilled, the capacitance of the measuring circuit, with an error not exceeding 1.25%, can be defined by the expression c 4 and at ds 0.5 pF (in the case of capacitors 15 and 1b should be equal to 1 pF) s (3) In this case, the measurement error of the capacitance of the oscillating circuit 5 due to instability d c is defined by the expression: (LAN (} - where ffuc - instability with (capacitors 15 and 16). Count of capacitance oscillatory circuit 5 at the resonant frequency, according to And with expression (3), is directly produced by frequency ratio block 18. The proposed device for measuring the quality factor of oscillatory circuits 5, as compared with the known, allows with relatively high accuracy to measure the capacitance of oscillatory circuits 5 in digital form in a wide frequency range, up to 300 MHz. Claim of the Invention A device for measuring the Q of oscillatory circuits, containing a tunable high-frequency oscillator, one output of which is connected to the first frequency input the modulator, the second input of which is connected to the output of the key, and the output of the frequency modulator through the oscillating circuit is connected to the input of the amplitude detector, the output of which is connected to the input of the resonant frequency search block, one output of the latter is connected to the input of the block of the second frequency derivative, and the other output is connected to the input of the first storage unit, the output of which is connected to the input of the tunable high-frequency generator, the key input is connected to one of the inputs of the frequency response unit and to the output peres traversed low-frequency generator, whose input is connected to the output of the second storage unit, the input of the latter is connected to the output of the nuorgan, the control inputs of the key, the first and second storage units, the frequency modulator, the resonant frequency search unit and the allocation unit of the second frequency derivative, respectively connected to the outputs of the control unit, characterized in that, in order to expand the functionality of the device, three additional keys and a chain of two are connected in series x capacitors and a frequency divider, and the output of a tunable high-frequency generator is connected through a serially connected first additional switch, the other. the input of which is connected to the input of the frequency modulator and the frequency divider with the input of the frequency ratio unit, and the first output of the second additional key is connected to the input of the zero-organ, the second and third outputs are respectively connected to the input and output of the allocation unit of the second frequency derivative, and two series-connected capacitors are connected between the input of the amplitude detector and a common bus, and the common output of a circuit of two series-connected capacitors is connected via a third additional switch to a common bus, the control input of which is respectively connected to the output of the control unit. Information sources. taken into account during the examination. 1. USSR author's certificate for application no. 2567339 / 18-21, cl. G 01 R 27/26, 09.01.78. 2. Author's certificate of the USSR, position No. 2 408263 / 18-21, cl. G 01 R 27/26, 01.10.76. a U6 S iM tn Sh} FIG. g