RU2024027C1 - Low-frequency instant-value digital phase and frequency meter - Google Patents

Abstract

FIELD: radio measurement technology. SUBSTANCE: device has two shapers, RS flip-flop, reference-voltage source, six electronic switches, three integrators, two comparators, two storage-retrieval units, two inverting amplifiers, control unit, complementing-pulse generator, two time selectors, two counters, one-shot multivibrator. EFFECT: improved design. 1 dwg

Description

 The invention relates to a radio engineering technique and can be used to measure the frequency and phase shift of slowly changing harmonic oscillations.

 Known digital low-frequency phase meter [1], which determines the value of the phase shift during two periods of the signal under study. The disadvantage of such a phase meter is the presence of an additional error due to a change in the frequency of the signal from period to period.

 Closest to the claimed device is a low-frequency meter of frequency and phase [2], which determines the values of frequency and phase shift. The disadvantage of this device is the long time to measure the frequency and phase and the lack of measurement and indication of the instantaneous frequency of the signal.

 The purpose of the invention is the reduction of measurement time.

 The goal is achieved in that the inventive device integrates a constant voltage during an exemplary time interval, as well as during a time interval proportional to the phase shift with subsequent simultaneous division of the obtained voltages into a voltage proportional to the period of the signal under study.

 The drawing shows a structural diagram of a low-frequency phasemeter-frequency meter.

 The device contains shapers 1 and 2, an RS-trigger 3, a reference voltage source 4, electronic keys 5 ... 10, first, second and third integrators 11 ... 13, first and second comparators 14 and 15, first and second nodes 16 and 17 sample-storage, the first and second inverting amplifiers 18 and 19, the control unit 20, the generator 21 counting pulses, the first and second time selectors 22 and 23, the first and second counters 24 and 25 pulses, single-shot 26.

 The first input of the meter through the former 1 is connected to the input S of the RS-trigger 3, the first input of the control unit 20, the second input of the meter through the former 2 is connected to the input R of the RS-trigger 3, the output of which is connected to the fourth input of the control unit 20. The reference voltage source 4 is connected to the input of the electronic key 5, the output of which is connected to a point combining the output of the electronic key 6 and the input of the first integrator 11, the output of which is connected to the combined inputs of the electronic keys 6, 7, 10 and sample-storage nodes 16 and 17. The output of the sample-storage unit 16 is connected to the input of the inverting amplifier 18, the output of which is connected to the input of the electronic key 8, the output of the sample-storage unit 17 is connected to the input of the inverting amplifier 19, the output of which is connected to the input of the electronic key 9. The input of the second integrator 12 is connected to a point combining the outputs of the electronic keys 7 and 8, and the output with the input of the first comparator 14, the output of which is connected to the second input of the control unit 20. The input of the third integrator 13 is connected to a point combining the outputs of the electronic keys 9 and 10, and the output is connected to the input of the second comparator 15, the output of which is connected to the fifth input of the control unit 20. The counter pulse generator 21 is connected to a point combining the inputs of the first and second time selectors 22 and 23, the outputs of which are connected to the inputs of the first and second pulse counters 24 and 25, respectively, the output of the first pulse counter 24 is connected to the third input of the control unit 20. The first output of the control unit 20 is connected to a point combining the control input of the key 5 and the input of the single-vibrator 26, the output of which is connected to the control input of the second bridle 17 of the sample-storage. The second, third, fourth, seventh outputs of the control unit 20 are connected respectively to the control inputs of the sample-storage unit 16, keys 6, 7, 10 and the second temporary selector 23, and the fifth output of the control unit 20 is connected to a point that combines the control inputs of the keys 8 and 9. The sixth output of the control unit 20 is connected to the control input of the first temporary selector 22.

 The device operates as follows.

Shapers 1 and 2 generate short pulses corresponding to the transition of signals U ₁ and U ₂ through zero from negative to positive values. At the output of the RS trigger 3, a pulse is generated whose duration Δ t corresponds to a phase shift Δφ.

·

U_o·dt = -

U_o·Δt , (1) где U_инт1 - выходное напряжение первого интегратора 11 за время Δ t;
τ₁ - постоянная времени первого интегратора 11;
Δ t - длительность импульса на выходе RS-триггера 3.The device has three working cycles. During the first cycle, which begins with the arrival of a pulse from the output Q of the RS flip-flop 3 to the fourth input of the control unit 20, the control unit 20 at the first output generates a pulse U ₁ *, which opens the key 5. A constant voltage U _{о is} applied to the input of the first integrator 11 from source 4. On the trailing edge of the pulse passing from the RS-flip-flop 3, the control unit 20 at the second output generates a pulse U ₂ *, allowing the voltage U _{int. 1} to be _written to the sampling-storage unit 16. By this time, the voltage at the output of the first integrator 11 will be
U _int. 1 = -

·

U _o dt = -

U _o · Δt, (1) where U _int1 is the output voltage of the first integrator 11 during the time Δ t;
τ ₁ is the time constant of the first integrator 11;
Δ t is the pulse duration at the output of the RS-trigger 3.

·

U_o·dt = -

U_o·T_o, (2) где Т_о - длительность импульса на выходе одновибратора 26.On the leading edge of the pulse coming from the first output of the control unit 20, a single-shot 26 is started, which, after a time T _o, generates a short pulse at the output, allowing the voltage U _int2 to be _written to the sample-storage unit 17. By this time, the output voltage of the first integrator 11 will take the value U _int2 :
U _int . ₂ = -

·

U _o dt = -

U _o · T _o , (2) where T _o is the pulse duration at the output of a single vibrator 26.

·

U_o·dt = -

U_o·T , (3) где Т - период колебаний исследуемого сигнала.With the arrival of the second pulse from the shaper 1, the key 5 is closed and the output of the integrator 11 will be voltage
U _int . ₃ = -

·

U _o dt = -

U _o · T, (3) where T is the period of oscillations of the investigated signal.

Thus, at the end of the first cycle, a constant voltage proportional to Δ t will appear at the output of the sample-storage node 16, a voltage proportional to the model time interval T _o will appear at the output of the sample-storage node 17, and a voltage proportional to the period at the output of the first integrator 11 T of the investigated signal.

At the beginning of the second clock, which begins when the key 5 is closed, the control unit 20 opens the electronic keys 8 and 9 with the signal U ₅ *. The voltage from the inverting amplifier 18 is supplied to the input of the second integrator 12, and the voltage from the inverting amplifier is input to the third integrator 13 19. At the same moment, the signal U ₆ * opens, the time selector 22 and the passage of the counting pulses from the generator 21 is allowed to the input of the counter 24.

·

(-U_инт.1·K₁·dt =

· t₂·U_инт.1;
(4)
U_инт.5= -

·

(-U_инт.2)·K₂·dt =

· t₃·U_инт.2;
(5) где U_инт4, U_инт5 - выходные напряжения соответственно второго и третьего интеграторов после второго такта интегрирования;
τ₂, τ₃ - постоянные времени соответственно второго и третьего интеграторов;
К₁, К₂ - коэффициенты передачи соответственно первого и второго инвертирующих усилителей 18 и 19;
t₂ - длительность второго такта t₂ = T - t_o.At the moment when the counter 24 is full, the second cycle will end, the second integrator 12 will be _charged to voltage U _int4 , and the third integrator 13 will be _charged to voltage U _int5 :
U _int . ₄ = -

·

(-U _int . _1; K _1; dt =

T ₂ U _int . ₁ ;
(4)
U _int . ₅ = -

·

(-U _int . ₂ ) K ₂ dt =

T ₃ U _int . ₂ ;
(5) where U _int4 , U _int5 are the output voltages of the second and third integrators, respectively, after the second integration cycle;
τ ₂ , τ ₃ - time constants, respectively, of the second and third integrators;
To ₁ , To ₂ - transmission coefficients, respectively, of the first and second inverting amplifiers 18 and 19;
t ₂ - the duration of the second measure t ₂ = T - t _o .

 Cons under the signs of the integrals show that the amplifiers 18 and 19 invert the signal.

·

U_инт.3·dt = -

·U_инт.3·t₃ (6) где t₃ - длительность третьего такта интегрирования при определении фазового сдвига
Δφ, t _φ = t_o + t₃
В момент времени, когда выходное напряжение третьего интегратора 13 станет равно 0, т.е. U_инт5 + U_инт7 = 0, на выходе второго компаратора 15 вырабатывается импульс U₅, поступающий на пятый вход блока 20 управления. На его седьмом выходе вырабатывается импульс U₇*, запрещающий прохождение счетных импульсов через второй временной селектор 23 на вход счетчика 25: U_инт.7= -U_инт.5= -

·

U_инт.3·dt = -

·U_инт.3·t₄ (7) где t₄ - длительность третьего такта интегрирования при определении частоты исследуемого сигнала f; t_f = t_o + t₄
Зная, что временные интервалы t₂, t₃, t₄ заполняются счетными импульсами генератора 21 с частотой f_o, получим:
t₂=

(8)
t₃=

(9)
t₄=

, (10) где N_o - число импульсов во втором такте;
N _φ , N_f - число импульсов в третьем такте соответственно при измерении фазового сдвига и частоты.With the beginning of the third integration step, when closed (U $\genfrac{}{}{0ex}{}{\text{*}}{\text{4}}$ , U ₇ ^* ) electronic keys 7 and 10, the voltage U _{int3 is} supplied to the inputs of the second and third integrators 12 and 13 from the output of the first integrator 11. Suppose that the capacitor of the second integrator is discharged earlier, and at the moment when the output voltage becomes zero, those. U _int4 + U _int6 = 0, at the output of the comparator 14, a pulse U _{2 is} generated, which is supplied to the second input of the control unit 20. At its sixth output, a pulse U ₆ * is generated, prohibiting the passage of counting pulses through the first time selector 22 to the input of the first counter 24:
U _int . ₆ = -U _int . ₄ = -

·

U _int . 3 dt = -

· U _int . ₃ · t ₃ (6) where t ₃ is the duration of the third integration step when determining the phase shift
Δφ, t _φ = t _o + t ₃
At the time when the output voltage of the third integrator 13 becomes equal to 0, i.e. U _int5 + U _int7 = 0, at the output of the second comparator 15, a pulse U _{5 is} generated, which is fed to the fifth input of the control unit 20. At its seventh output, a pulse U ₇ * is generated, prohibiting the passage of counting pulses through the second time selector 23 to the input of the counter 25: U _int . ₇ = -U _int . ₅ = -

·

U _int . 3 dt = -

· U _int . ₃ · t ₄ (7) where t ₄ is the duration of the third integration step when determining the frequency of the studied signal f; t _f = t _o + t ₄
Knowing that the time intervals t ₂ , t ₃ , t ₄ are filled with counting pulses of the generator 21 with a frequency f _o , we obtain:
t ₂ =

(8)
t ₃ =

(9)
t ₄ =

, (10) where N _o is the number of pulses in the second cycle;
N _φ , N _f - the number of pulses in the third cycle, respectively, when measuring the phase shift and frequency.

= -K₁·t₂·

(11)
t₄= -K₂·t₂·

= -K₂·t₂·

(12) с учетом выражений (1) - (3), (8) - (10):
N_φ = -K₁·N_o·

= -K₁·N_o·φ_x= K₃·φ_x
(13)
N_f = -K₂·N_o·

= -K₁·N_o·f_x= K₄·f_x
(14)
Выбирая значение К₃ кратным 36, а К₄ - 10, можно получить отсчет фазового сдвига в градусах, частоты - в герцах.Solving equations (6) and (7) with respect to t ₃ and t ₄ :
t ₃ = -K ₁ · t ₂

= -K ₁ · t ₂ ·

(eleven)
t ₄ = -K ₂ · t ₂

= -K ₂ · t ₂ ·

(12) taking into account expressions (1) - (3), (8) - (10):
N _φ = -K ₁ · N _o ·

= -K ₁ · N _o · φ _x = K ₃ · φ _x
(thirteen)
N _f = -K ₂ · N _o ·

= -K ₁ · N _o · f _x = K ₄ · f _x
(14)
Choosing the value of K _{3 as a} multiple of 36, and K ₄ as a factor of 10, you can get the phase shift count in degrees, and frequencies in hertz.

 Thus, in the proposed device, it is possible to simultaneously measure the frequency and phase of the studied signals.

Claims (1)

 INSTANT DIGITAL FREQUENCY PHASOMETER-FREQUENCY INSTRUMENT VALVES, containing a pulse counter, two shapers, four electronic keys, a control unit, a counter pulse generator, an RS-trigger, a voltage reference source, an integrator, a comparator, two sample-storage units, an inverting amplifier, a time selector, the inputs of the former are the inputs of the device, the output of the first driver is connected to the S-input of the RS-trigger and the first input of the control unit, the output of the second driver is connected to the R-input of the RS-trigger, output which is connected to the fourth input of the control unit, the output of the reference voltage source is connected to the input of the first electronic key, the output of which is connected to the integrator input and the input of the second electronic key, the output of which is connected to the integrator output and the inputs of the first and second sampling-storage nodes, the output of the first node sample-storage through an inverting amplifier is connected to the input of the fourth key, the output of which is connected to the output of the third electronic key, the first, second, third, fourth, fifth and sixth the moves of the control unit are connected respectively to the control inputs of the first electronic key, the first sampling-storage unit, the second, third and fourth electronic keys and the temporary selector, and the second and third inputs of the control unit are connected respectively to the outputs of the comparator and pulse counter, and the counter pulse generator the time selector is connected to the input of the pulse counter, characterized in that, in order to reduce the measurement time, the fifth and sixth electronic keys, the second and third integrators, second inverting amplifier, second comparator, second time selector, second pulse counter and one-shot, and the input of the sixth electronic key is connected to the output of the first integrator, and the output of the second sample-storage node through the second inverting amplifier is connected to the input of the fifth electronic key, output which is combined with the output of the sixth electronic key and the input of the third integrator, the output of which is connected to the input of the second comparator, the output of which is connected to the fifth input of the unit II, the input of the first comparator through the second integrator is connected to the output of the third electronic key, the input of which is connected to the output of the counter pulse generator, and the output to the input of the second pulse counter, the control input of the fifth electronic key is connected to the fifth output of the control unit, the first output of the control unit is connected with a single vibrator, the output of which is connected to the control input of the second sampling-storage unit, the seventh output of the control unit is connected to the control inputs of the sixth electronic key and the second temporarily th selector.

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