EA007802B1 - Device for signal parameters and resistances measurement in three program wired radio network - Google Patents

Abstract

The Invention relates to measuring technology, in particular to devices, for measurement of signal parameters in three program wired radio networks and resistances of networks.The invention is characterized in that units, which increase functional potentialities of the instrument and allow measurement constant voltages, voltages of industrial frequency, resistance of networks to alternating current on three frequencies (0,4; 78 and 120 kHz) with high accuracy, are inserted in the instrument, intended for alternating voltages measurement in three program wired radio networks and direct-current resistance measurement. The input circuits of channel for measurement direct and alternating voltages are made symmetrically, Circuits of transformation AM signals of second and third programs are executed on superheterodyne scheme with key mixer. The digital synthesizer of frequencies, feedback shift register, DAC and synchronous detectors are placed in channel of alternating-current resistance measurement. This device also has the microcontroller, controlled by console, and symbol display.The technical effect of using this device is increasing measurement accuracy of signal parameters and accuracy of direct-current resistance lines measurement, as well as functional enhancements of device, especially possibility of network impedance measurement.

Description

The invention relates to measuring equipment. Specifically, to devices designed to measure the parameters of signals in three-program wire broadcast networks and network resistance.

The known meter complex impedance networks of three-program wire broadcasting [1], containing a battery of galvanic cells, cascade connected alternating voltage generator, generating signals at four frequencies of the first channel: 0.4; 3, 6 and 10 kHz and at frequencies of the second and third channels in the range 68-88 kHz and 110-130 kHz, an amplifier with adjustable gain and a transformer having six secondary windings, cascade-connected three-channel bandpass filter, the first input of which is connected to the first terminal of the transformer, a constant gain amplifier, a detector and a dial indicator, a voltage divider consisting of two series-connected resistors and connected between the first and second terminals of the transformer, the first and second switches, reactivity shop, the first end of which is connected to the first meter input, the first meter output is connected to the connection point of the voltage divider resistors, and the second output is connected to the second input of a three-channel bandpass filter, a node consisting of five series-connected reference resistors and connected by the beginning of the first resistor with the first output of the transformer, the first and second paired five-channel switches, the input of the second of which is connected to the second input of the meter and the input of a two-channel switch The switch, the conclusions of the first of the five-channel switches can alternately connect to the second, third, fourth, fifth and sixth terminals of the transformer, and the conclusions of the second - alternately connected to the junction points of the first and second, second and third, third and fourth, fourth and fifth and end the fifth reference resistors, while the input of the first of the five-channel switches through the first switch can be connected to the first meter input, and the second end of the inductance store through the second switch can connect with the input of the first five-channel switch and through the first switch with the second input of the meter. The disadvantages of the device are the narrow scope (the device can only be used to measure AC resistance), a small range of measured resistances, manual selection of measurement limits, low immunity, frequent replacement of the power source.

A known indicator of measurement is intended for measuring alternating and constant voltages in three-program broadcast networks and direct current network resistance, the circuit of which is also given in [1]. The device contains a channel for measuring the effective values of alternating voltages, a channel for measuring constant voltages and a channel for measuring resistances. It has four single-ended inputs: an AC voltage input, a DC voltage input, an “K * 1” input, and an “K * 100” input. The device contains an arrow indicator, a switch of the limits of the scales of an arrow indicator: 1.5; 6; thirty; 150 and 300 V, work switch: “LF”, “78 kHz”, “120 kHz”, “Upost” and “Ohm”, voltage dividers connected to the named switches, one low-pass filter and two high-frequency band-pass filters introduced one into the channel for measuring alternating voltages using switches, a detector connected by its input to the output of any of the three filters, and its output to a switch indicator, and a battery of galvanic cells located in the channel for measuring resistances. The drawbacks of the device are low sensitivity in measuring voltages (0.5 V), high measurement error due to mutual interference between channels, the impossibility of measuring the amplitude of signals of broadcasting programs, manual selection of the limits of the dial gauge scale.

The closest to the claimed device is a technician's circular call call [2], which measures the voltage of broadcasting and service signals in three-program wire broadcasting networks, estimates the maximum voltage of network signals during broadcast transmission, and monitors the insulation resistance of wired broadcasting lines of direct current. The prototype device contains the first two-channel switch, which serves as a switch of measured parameters, the common input of which is the device input, the first step-down voltage divider, whose input is connected to the first output of the first two-channel switch, a low-pass filter providing the first program signals (0.05 - 10 kHz), the first, second and third bandpass filters, the first of which ensures the transmission of signals from the second program (78 ± 4) kHz, the second - the transmission of signals from the third of the third program (120 ± 4) kHz, and the third - the transmission of service signals (13-16 kHz), while the inputs of all four filters are connected to the output of the first step-down voltage divider, four-channel channel switch, the first, second, third and fourth inputs of which are connected , respectively, with the outputs of the first, second, third and fourth named filters, cascaded connected to the second stage voltage divider, the input of which is connected to the common output of a four-channel switch, and an AC voltage amplifier, detector rms ac voltage and quasi-peak detector, the inputs of which are connected to the output of the ac voltage amplifier, dc amplifier, the input of which is connected to the output of the quasi-peak detector, the second two-channel switch, the first and second inputs of which are connected respectively to the output of the rms detector and the output of the dc amplifier , measuring unit of resistance to direct current, the input of which is connected to the output of the first two-channel trans

- 1 007802 key switch, the third two-channel switch, the first input of which is connected to the output of the second two-channel switch, and the second input - with the output of the unit for measuring the resistance of networks of direct current, a dial instrument with protection elements connected to the output of the third two-channel switch, sound control unit, connected to a separate input of the AC voltage amplifier, and a battery of galvanic cells. The device prototype has the following disadvantages. The device does not measure DC voltage and AC voltage of electrical networks with a frequency of 50 Hz. It has a high measurement error of alternating voltages in wire broadcast networks (± 15%), asymmetrical input, high measurement error of resistances to direct current (± 30%), low input resistance (from 5 to 100 kΩ), cannot determine the impedance of the circuits on the frequencies of the signals of the first, second and third programs, requires frequent replacement of power supplies.

The technical effect, the achievement of which the proposed solution is aimed at, is to increase the measurement accuracy of signal parameters and the measurement accuracy of DC line resistance, as well as enhancement of functionality (measurement of the impedance of broadcasting circuits to alternating current).

This is achieved by the fact that in a device for measuring parameters of signals in three-wire wire broadcast networks and resistance to direct-current networks, which contains a switch of measured parameters, having a common input, which is a device input, a step-down voltage divider, whose input is connected to the first output of a switch of measured parameters, DC network resistance measurement unit, the input of which is connected to the second output of the named switch, AC voltage amplifier, first and second de The second of which are made quasi-peak, a high-pass filter, a sound control unit and a power source, a switch of measured parameters is made three-channel with a balanced input and outputs, a step-down voltage divider is made with a symmetrical input and output, and an antiphase voltage adder is added to the device, its input is connected to the output of a step-down voltage divider, and its output is connected to the input of a high-pass filter, a key mixer, the signal input of which is connected to the output ohm high-pass filter, intermediate frequency amplifier, whose input is connected to the output of a key mixer, and its output - to the input of the first detector, microcontroller, to the first and second inputs of which a frequency defining element is connected and based on the elements of which a reference oscillator is formed with a switchable frequency of the output signal in the form of a meander, ending with the first output of the microcontroller, an analog-to-digital converter, ending with the third-seventh inputs of the microcontroller, the third input of which is connected to The output of the second detector, and the counting interface, terminating in the second to fourth outputs of the microcontroller, a digital frequency synthesizer whose input is connected to the first output of the microcontroller, cascade-connected a shift register with feedback, the input of which is connected to the output of the digital frequency synthesizer and the control input of the key mixer , a digital-to-analog converter, the eight inputs of which are connected to eight outputs of a shift register with feedback, and the first low-pass filter whose input is connected inen with the output of a digital-to-analog converter, and its output is connected to the input of an AC voltage amplifier, an impedance measurement unit for AC networks, the balanced input of which is connected to the first and second terminals of the third channel of the measured parameters switch and which includes a resistor connected by its input to the output AC voltage amplifier, and its output to the first output of the third channel of the switch, the first node of the reference resistance, consisting of several resistors and switch node and connected between the second output of the third channel switch and common to the entire device conductor, the first and second synchronous detectors, the signal inputs of which are connected to the first and second terminals of the third channel of the switch, and the control inputs with one of the outputs of the shift register with feedback, and the second and third low-pass filters connected between the outputs of the first and second synchronous detectors and the fourth and fifth inputs of the microcontroller, an alphanumeric indicator whose inputs are connected to volts the fourth output of the microcontroller, and a manual control unit, the outputs of which are connected to the eighth to thirteenth inputs of the microcontroller, the direct current resistance measurement unit contains a DC source connected to the first output of the second channel of the measured parameter switch with its output, consisting of as well as the first one of several resistors and a switching node and connected between the second output of the second channel of the switch and the device common for the whole device ovodnikom, and fourth and fifth low pass filters connected between the first and second terminals of the second switch channel and the sixth and seventh input of the microcontroller, wherein the second input of the two-channel switch is connected to the output of the adder antiphase voltages, and the output of the switch - the second detector inputs.

In particular cases, a three-channel switch, a two-channel switch and a step-down voltage divider are electrically controlled, the control inputs of which are connected to the fifth, sixth and seventh outputs of the microcontroller, the composition of the step-down voltage divider

- 2 007802 an amplifier was inserted, and the second detector was made full-wave based on two operational amplifiers.

The functional diagram of the proposed device for measuring parameters of signals in three-program wire broadcasting networks and network resistance is shown in FIG. 1, on which is marked:

- symmetric three-channel switch of the measured parameters;

- symmetric step voltage divider;

- adder of antiphase constant and variable voltages;

- high pass filter (HPF);

- key mixer;

- intermediate frequency amplifier (amplifier);

- first detector;

- two-channel switch;

- sound control node;

- second detector (quasi-peak);

- microcontroller;

- frequency setting element;

- analog-to-digital converter (ADC);

- alphanumeric indicator;

- digital frequency synthesizer;

- shift register with feedback;

- digital-to-analog converter (DAC);

- the first low pass filter (LPF);

- AC voltage amplifier;

- unit for measuring the resistance of networks to alternating current;

- resistor;

- the first node of the reference resistance;

- the first synchronous detector;

- the second synchronous detector;

- second low pass filter;

- the third low pass filter;

- DC resistance measurement unit;

- DC source;

- the second node of the reference resistance;

- Fourth lowpass filter;

- the fifth low pass filter;

- manual control;

- power supply.

The proposed device provides:

- measurement of root-mean-square and quasi-peak voltages of the audio frequency in the range of 0.05-10 kHz, including measurement of the quasi-peak signal level of the first program and the root-mean-square value of the voltage of industrial frequency networks 50 Hz;

- measurement of the rms and quasi-peak voltages of the envelopes of the amplitude-modulated (AM) signals of the second and third programs, the carrier frequencies of which are 78 and 120 kHz;

- measurement of constant voltage;

- measurement of resistance to direct current networks;

- determination of network impedance at frequencies of 0.4; 78 and 120 kHz.

Measurement of alternating and constant voltages is performed when the first channel of switch 1 is open (when its input is connected to the first output). The audio frequency of the first program, or the AM signal of the second or third program signal, or the sinusoidal voltage of the industrial frequency, or the constant voltage (depending on the type of the measured voltage) passes through a stepped voltage divider 2, the antiphase voltage adder 3 and enters simultaneously to the HPFC input 4 , having a cut-off frequency of 50 kHz, and to the second input of the two-channel switch 8. The high-pass filter 4 transmits only AM signals of the second and third programs. From the output of the high-pass filter 4 AM, the signal is fed to the input of the key mixer 5, the control input of which is supplied with voltage from the frequency synthesizer 15, which has the form of a square wave and a frequency equal to the sum of the average frequency of the frequency amplifier 6 and the second or third program carrier frequency. From the output of the key mixer 5, the transformed signal is fed to the IF amplifier 6, where it is filtered and amplified, and then to the first detector 7, which emits a low-frequency (LF) AM oscillation envelope (sound frequency signal). From the output of the detector 7, the low frequency signal arrives at the first input of the switch 8. When the first channel of the switch 8 is turned on, its output receives the modulating low frequency signal of the second or third program (depending on the frequency of the square wave fed to the control input of the key mixer 5). Superheterodyne reception

- 3 007802 of the second and third programs allows to reduce the additional measurement error due to the interfering effects of signals from neighboring programs. LF voltages, including the voltages of the first program signals, are measured when the second channel of switch 8 is turned on. Voltage from the output of switch 8 simultaneously enters the input of the audio control unit 9, the input circuit of which has a coupling capacitor that cuts DC voltage and quasi-peak input detector 10. From the output of the last detected signal or a constant voltage passed from the input of switch 1, is fed to the second input of the microcontroller 11 (to one of the inputs of the A / D converter 13), where converted to a digital signal that undergoes further conversion. When you press the buttons on the hand control 32, the microcontroller 11 calculates the root-mean-square or amplitude value of the low-frequency voltages or calculates the constant voltage, the values of which are displayed on the screen of the alphanumeric indicator 14.

An additional amplifier, introduced into the composition of the step-down voltage divider 2, and the second detector 10, containing two operational amplifiers, increase the sensitivity of the device when measuring alternating and constant voltages.

As a frequency-generating element 12, the device uses a quartz resonator manufactured at a resonant frequency of 8 MHz. From the first output of the microcontroller 11, the signal in the form of a meander of the frequency required for this type of measurement is fed to the input of a digital frequency synthesizer 15 containing its internal frequency divider. The signal from the output of the frequency synthesizer 15 is supplied simultaneously to the control input of the key mixer 5 and to the input of the shift register with feedback 16. The shift register is used in the channel designed to measure the impedance of the AC networks. Key mixer 5 with respect to a conventional mixer provides a more stable level of the converted signal, which improves the accuracy of voltage measurements.

Measurement of the resistance of networks to direct current is made when the second channel of switch 1 is open. In this case, two conductors of broadcasting networks are connected to the device input and the resistance of the networks is connected between the output of the DC source 28 and the input of the second node of the reference resistances 29. From the connection points of the conclusions of the second channel of the switch 1 with the output of the DC source 28 and the input of the second node of the reference voltage resistors 29 are fed to the inputs of the fourth 30 and fifth 31 LPF having a frequency 40 Hz cutoff. From the output of the filters 30 and 31, the constant voltages go to the third and fourth inputs of the microcontroller 11 and further to the inputs of the ADC 13. The measured resistance is calculated by the microcontroller 11 after pressing one of the buttons on the remote control 32 using the formula where ib and ϋ7 are the voltages at the sixth and seventh the inputs of the microcontroller 11, proportional to the values of the voltages at the inputs of the device (voltages are removed relative to the total conductor device),

K _E2 - the resistance value of the second node of the reference resistances 29. The numerical value of the measured resistance is displayed on the screen of the alphanumeric indicator 14.

Measurement of the impedance of networks AC current is carried out at frequencies of 0.4; (78 ± 0.78) and (120 ± 1.2) kHz with the open third channel of the switch 1. The sinusoidal voltage at these frequencies is formed by a cascade connected microcontroller 11, digital frequency synthesizer 15, shift register 16, DAC 17 and low pass filter 18. The input of the shift register 16 receives the voltage in the form of a meander. The voltages on the eight outputs of the register 16 also have the form of a meander, but the frequency is 16 times lower than the frequency of the input meander. At the outputs of the register, the meanders are shifted in time successively by the outputs for the duration of one, two, etc. up to eight periods of the input meander (input meander pulses for register 16 can be considered as clock). The feedback circuit in the register ensures the formation of an impulse on any of its outputs, the duration of which is equal to the duration of eight periods of the input meander. At the output of the DAC 17, the signal has a quasi-harmonic form. The low-pass filter 18 having a cut-off frequency of 130 kHz removes higher harmonics from the quasi-harmonic signals of the second and third programs. Next, the alternating voltage of one of the three frequencies (0.4; 78 or 120 kHz) is fed to the input of the amplifier 19, and from the output of the amplifier to the first output of the resistor 21, the second output of which is connected to the first output of the third channel of the switch 1 (the second output of the resistor 21 together with the conductor common to the device, forms the output of the alternator, which consists of a cascade connected microcontroller 11, a digital frequency synthesizer 15, a shift register with feedback 16, a DAC 17, the first LPF 18, an amplifier 19 and a resistor 21). To the second output of the third channel of the switch 1 is connected the first node of the reference resistances 22. When connected to the input of the broadcasting network device, its resistance is turned on between the second output of the resistor 21 and the first node of the reference resistances 22. Voltage taken from the second end of the resistor 21 and the input of the reference resistance node 22, are fed to the inputs of the first 23 and second 24 synchronous detectors, the control inputs of which receive the meanders

- 4 007802 with the same frequency as the frequency of the sinusoidal signal coming from the output of the resistor 21. The control inputs of the synchronous detectors 23 and 24 are connected to one of the bits of the register 16, the phase of the signal at which approximately coincides with the phase of the sinusoidal signal approximately coincide in time with the moments of the transition of the polarity of the sinusoidal voltage through zero). From the output of synchronous detectors, the detected (rectified) voltages are fed to the inputs of the second 25 and third 26 LPF having a cut-off frequency of 40 Hz, from the output of which are constant voltages proportional to the input variables present on the first and second terminals of the third channel of the switch 1 voltages, go to the fifth and the sixth inputs of the microcontroller 11, in which and processed.

The value of the impedance of the AC network is determined after determining the resistance of the network to a direct current. An equivalent circuit diagram for an alternating current containing a reactive component is displayed by an electrical circuit from parallel-connected resistance (resistance to direct current) and capacitance, or from series-connected active resistance and inductance.

In the first case, the circuit shown in FIG. 2, and in the second case, the circuit shown in FIG. 2b. FIG. 2a and 2b, K _E1 denotes the known resistance of the first node of the reference resistors 22, and _E1 is the alternating voltage between the conductor common to the whole device and the input of the node 22, and _{0 indicates the} alternating voltage between the conductor common to the whole device and the output of the resistor 21, K - active resistance (resistance of a direct current circuit).

For the circuit shown in FIG. 2a:

³¹ 1 + gy7 ² C ² I ²⁾ L _e /. (1 + et ² C ² nd ² ) ²

For the circuit shown in FIG. 2b:

io ² = (i + i _{e |} ) ² 4¾ ² ^ ¾ ² (1) (2)

In expression (1), the unknown value is the equivalent capacitance C, in expression (2), the equivalent inductance Γ of the network being measured.

The calculation of the value of the equivalent capacitance or inductance is made after determining the value and ₀ at frequencies of 0.4; 78 and 120 kHz. With increasing and ₀ with increasing frequency, the measured resistance contains an inductive component, with decreasing - capacitive. After determining the nature of the reactivity, the measurement is performed and ₀ and and _E1 at the required frequency (0.4; 78 or 120 kHz) and the calculation of C or G. The impedance of the measured circuit containing the capacitance has the form containing inductance

Ζ ₇ = 7? + / ννΔ.

Since the DC voltages at the outputs of the low-pass filter 25 and 26 are proportional to both ₀ and _E1 , then the fourth and fifth inputs of the microcontroller receive direct voltages proportional to the input variables.

Synchronous detectors 23 and 24 reduce the measurement error of the impedances of the broadcasting circuits.

When electrically controlled three-channel switch 1, two-channel switch 8 and step-down voltage divider 2 are switched, the microcontroller switches them by pressing the corresponding buttons on the hand control 32.

In relation to the prototype device, the proposed device has enhanced functionality. It allows measuring the resistance of networks to alternating current at frequencies of three programs (the prototype does not allow this), has a smaller measurement error of constant voltages (± 10% against ± 15% in the prototype), a smaller measurement error of resistance to direct current (± 10% against ± 30 % in the prototype), higher sensitivity measurement of constant voltages (10 mV versus 30 mV in the prototype), higher input resistance (10-450 kΩ against 5-100 kΩ in the prototype). The noise immunity of the proposed device is also higher than that of the prototype due to symmetrical input circuits, superheterodyne amplification of the signals of the second and third programs, the use of a key mixer and two synchronous detectors.

The power source of the device manufactured by us was made universal - it was powered from an AC network and had a battery with a charger and did not require frequent replacement of batteries of galvanic cells, which took place in the device-prototype.

Sources of information used in the preparation of the description of the invention:

1. Multi-program wired broadcasting / V.I. Dzyadchik, S.A. Zaslavsky, B.N. Filatov, A.V. Shershakova. M .: Communication, 1974, p.208-214.

2. Measuring instrument of a circular call. Technical description and instruction manual

- 5 007802 tats Zv2.746.012 THAT. Kharkov Intercollegiate Printing Company, Kharkov, 1988 prototype.

Claims (4)

CLAIM 1. A device for measuring signal parameters in networks of three-program wire broadcasting and resistance of direct current networks, containing a switch of measured parameters, having a common input that is the input of the device, a step voltage divider, the input of which is connected to the first output of the switch of measured parameters, a network resistance measurement unit direct current, the input of which is connected to the second output of the named switch, an AC amplifier, the first and second detectors, of which the swarm is made quasi-peak, a two-channel switch, the first input of which is connected to the output of the first detector, a high-pass filter, an audio control unit and a power source, characterized in that the switch of the measured parameters is made three-channel, with symmetrical inputs and outputs, a step voltage divider is made with a symmetric input both the output and the composition of the device additionally include an antiphase voltage adder, the input of which is connected to the output of the step voltage divider, and its output is connected to the input a high-pass filter house, a key mixer, the signal input of which is connected to the high-pass filter output, an intermediate-frequency amplifier, the input of which is connected to the output of the key mixer, and its output - with the input of the first detector, a microcontroller, to the first and second inputs of which a frequency-setting element is connected and based on the elements of which a reference oscillator is formed with a switchable frequency of the output signal in the form of a meander, ending with the first output of the microcontroller, an analog-to-digital converter, eye numbered by the third-seventh inputs of the microcontroller, the third input of which is connected to the output of the second detector, and a counting-deciding interface ending with the second-fourth outputs of the microcontroller, a digital frequency synthesizer, the input of which is connected to the first output of the microcontroller, cascade-connected shift register with feedback, the input of which is connected to the output of the digital frequency synthesizer and the control input of the key mixer, a digital-to-analog converter, eight inputs of which are connected to eight outputs feedback shift register, and the first low-pass filter, the input of which is connected to the output of the digital-to-analog converter, and its output is connected to the input of an alternating voltage amplifier, a unit for measuring the network impedance to alternating current, a symmetric input of which is connected to the first and second terminals of the third switch channel of measured parameters and which includes a resistor connected by its input to the output of the AC voltage amplifier, and by its output - to the first output of the third channel, switch I, the first node of the reference resistances, consisting of several resistors and a switching node and connected between the second terminal of the third channel of the switch and the conductor common to the entire device, the first and second synchronous detectors, the signal inputs of which are connected to the first and second terminals of the third channel of the switch, and the control inputs - with one of the outputs of the shift register with feedback, and the second and third low-pass filters included between the outputs of the first and second synchronous detectors and the fourth and fifth the inputs of the microcontroller, an alphanumeric indicator, the inputs of which are connected to the second four-fourth outputs of the microcontroller, and the manual control, the outputs of which are connected to the eighth to thirteenth inputs of the microcontroller, the unit for measuring the resistance of direct current networks contains a direct current source connected to the first output of the second channel switch of the measured parameters, the second node of the reference resistances, consisting as well as the first of several resistors and a switching node, and including between the second terminal of the second switch channel and the conductor common to the entire device, and the fourth and fifth low-pass filters connected between the first and second terminals of the second channel of the switch and the sixth and seventh inputs of the microcontroller, while the second input of the two-channel switch is connected to the output of the antiphase voltage adder , and its output is with the input of the second detector and the input of the sound control unit. 2. The device according to claim 1, characterized in that the three-channel switch, two-channel switch and a step voltage divider are electrically controlled, the control inputs of which are connected to the fifth, sixth and seventh outputs of the microcontroller. 3. The device according to claim 1 or 2, characterized in that an amplifier is included in the composition of the step voltage divider. 4. The device according to claim 1 or 2, characterized in that the second detector is made half-wave based on two operational amplifiers.