RU2018955C1 - Device for modelling impulse noise - Google Patents

Abstract

FIELD: computer technology. SUBSTANCE: two-pole pulse is formed, which has preset shape and duration by means of introducing the second controlling switch 5, the second power accumulator 7, smoothing diode 3, sync generator 15 and commutation unit 8. Solenoid is used as a load. When nth positive impulse with formed shaped and preset duration passes through thyristor 29, primary winding of isolation transformer 10, thyristor 32 to commutation unit, the positive polarity impulse is formed onto output terminals 11. When 2 nth (where n= 1,2,3. . .) enters commutation unit through thyristor 32, primary winding of isolation transformer 10, thyristor 30, the pulse with reverse polarity is formed on terminals 11. As a result two-pole pulses with preset shapes and durations are formed in load. EFFECT: widened functional capabilities; improved precision of modelling of impulse noise. 2 cl, 2 dwg

Description

 The invention relates to analog computing and can be used in testing equipment for noise immunity.

 A device for simulating impulse noise, containing the studied equipment, a filter, the inputs of which are connected to a source of supply voltage, and the inputs through isolation capacitors are connected to a load resistor and to the input of the drive connected to an additional source of supply voltage, as well as a thyristor pulse shaper controlling whose inputs are connected to a pulse generator [1].

 The disadvantages of the known device are low efficiency and low speed due to the complete discharge of the drive to the limiting resistor of the thyristor pulse shaper after the formation of a rectangular pulse on the load (otherwise the shunt thyristor will not turn off), as a result of which almost all the stored energy of the drive is released on the limiting resistor, which determines increased energy consumption by an additional power source for the charge of the drive and an increase in the charge time of the drive.

 The closest in technical essence to the proposed technical solution is a device for modeling impulse noise, having significant efficiency and speed, containing the first source of supply voltage, a filter, an isolation transformer, a master oscillator, a thyristor pulse shaper, a load resistor, a limiting resistor, a drive, a second source power supply connected to the inputs of the drive, one output of which is directly, and the other through a limiting resistor connected to the input m of a thyristor pulse shaper connected by control inputs to the outputs of the master oscillator, and outputs with a load resistor and through an isolation transformer from one of the filter output buses, the filter inputs being connected to a power supply source, a controlled key whose outputs are connected in parallel with the thyristor pulse shaper, and control inputs - to additional inputs of the master oscillator [2].

 However, in this device for simulating impulse noise, it is not possible to generate bipolar impulse noise of a given shape and duration.

 The aim of the invention is to expand the functionality of the device by forming bipolar pulses of a given shape and duration.

 The goal is achieved in that a device containing a first source of supply voltage, a filter, an isolation transformer, a master oscillator, a thyristor pulse shaper, load and limit resistors, an energy storage device, a second power supply, a controlled key, a second controlled key, a second energy storage device are introduced, a smoothing diode, a clock generator and a switching unit, the information input of which is connected to the second output of the limiting resistor, while the first and second outputs of the switching unit are sub are connected to the terminals of the primary winding of the isolation transformer, the first terminal of the second controlled key is connected to the first terminal of the pulse shaper, the second terminal of which is connected directly to the second terminal of the second controlled key and connected to the other terminal of the first energy storage connected to the anode of the smoothing diode through the second energy storage device, the third output of the switching unit, the common bus of the first power source and the outputs of the clock, the clock input of which is connected to the second output adayuschego generator smoothing diode cathode connected to a first terminal of the first controllable switch.

 The second controlled key contains a thyristor and an inductor connected in series, shunted by a resistor and a diode connected in series, the cathode of which is connected to the first terminal of the second controlled key and the thyristor anode, the control electrode and cathode of which are the control input of the second controlled key, and the second terminals of the inductor and resistor are the second output of the second managed key.

 The switching unit contains two parallel-connected circuits, each of which includes two serially connected controlled thyristors, and the anodes of the first two controlled thyristors are the information input of the block, the first and second outputs of which are the cathodes of the first controlled thyristors of the first and second chains, respectively, the control inputs of the first controlled thyristor the first chain and the second controlled thyristor of the second chain are connected to the first control input of the clock generator and are the first m is the control input of the unit, the second control input of which is the combined control inputs of the second controlled thyristor of the first circuit and the first controlled thyristor of the second chain connected to the second control output of the sync generator.

 A comparative analysis with the prototype revealed signs of the proposed technical solution that are not similar to the signs of the prototype, namely the second controlled key, the second energy storage device, a smoothing diode, a clock generator and a switching unit, the information input of which is connected to the second output of the limiting resistor, the first and second outputs the switching unit is connected to the terminals of the primary winding of the isolation transformer, the first terminal of the second controlled key is connected to the first terminal of the driver s, the second output of which is connected to the second output of the second managed key directly and through the second energy storage device is connected to another output of the first energy storage device connected to the anode of the smoothing diode, the third output of the switching unit, the common bus of the first power source, the outputs of the clock generator, the clock input of which is connected with the second output of the master oscillator, the cathode of the smoothing diode is connected to the first output of the first controlled key. Thus, the proposed technical solution meets the criterion of "Novelty."

 The proposed technical solution, while preserving the other properties of the known device for modeling impulse noise, allows you to generate impulse noise of a given shape and duration and thereby expand the scope of the equipment noise immunity tests.

 An analysis of the known technical solutions showed that there are no signs distinguishing the proposed solution from the prototype, therefore, the proposed solution has "significant differences".

 In FIG. 1 schematically shows a device for modeling bipolar impulse noise of a given shape and duration; figure 2 - control pulses and timing diagrams.

 A device for modeling bipolar impulse noise of a given shape and duration contains a power source 1, the first and second conclusions of which are connected to the input and the common bus of the first energy storage 2. The output of the latter is connected to the cathode of the equalizing diode 3, the first output of the managed key 4, the input of the second managed key 5, the first input of the pulse shaper 6. The output of the second controlled key 5 is connected to the second input of the pulse shaper 6 and to the input of the second energy storage device 7, the output of which is connected to the common bus of the power supply 1, the anode of the equalizing diode 3, and the third output of the switching unit 8. The information input of the switching unit 8 through the limiting resistor 9 is connected to the first and second outputs of the pulse shaper 6, the input of the controlled key 4, the output of the switching unit is connected to the primary winding of the isolation transformer 10, the secondary winding of which is connected to the output terminal 11 and the output of the filter 12, the input of which connected to the output of the second power source 13. The first and second control inputs of the key 4 are connected to the beginning and end of the secondary winding of the first isolation transformer, respectively, the primary winding of which is connected to the first output channel of the driving generator 14. The first control input and the first output of the pulse shaper 6 are connected to the beginning and end of the secondary winding of the second isolation transformer respectively, the primary winding of which is connected to the second output channel of the master oscillator 14 and the clock input of the clock generator. The first and second control inputs of the key 5 are connected to the beginning and end of the secondary winding of the third isolation transformer, respectively, the primary winding of which is connected to the third output channel of the driving generator 14. The second control input and the second output of the pulse shaper 6 are connected to the beginning and end of the secondary winding of the fourth isolation transformer the primary winding of which is connected to the fourth output channel of the master oscillator 14. The first control input and the third output of the switching unit 8 with a unified control output timing generator 15. The second control input and a third output of the switching unit 8 connected to the second control output of the clock generator 15.

 The first energy storage device 2 comprises a reactor 16 and a capacitor 17, the first terminal of the reactor 16 being connected to the output of the power source 1, the second terminal being connected to the first lining of the capacitor 17, the second lining of which is connected to the common bus of the power source 1.

 The first controlled switch 4 contains a diode 18, a diode 19 and a series connection of a capacitor 20, an inductance 21, a thyristor 22, the cathode of which is connected to the output of the switch 4, the cathode of the diode 18, and the anode of the diode 19, while the control electrode and the cathode of the thyristor 22 are connected respectively to the control the inputs of the key 4, the anode of the thyristor 22 is connected to the cathode of the diode 19, the anode of the diode 18 is connected to the first input of the control key 4 and the second lining of the capacitor 20.

 The second controlled key 5 contains a serial connection of the thyristor 23, an inductor 24, shunted by a serial connection of a resistor 25 and a diode 26, the cathode of which is connected to the input of the key 5 and the anode of the thyristor 23, while the second output of the resistor 25 is connected to the output of the key 5.

 The pulse shaper 6 contains thyristors 27 and 28, the anodes of which are connected to the first and second inputs of the pulse shaper 6, respectively, and the cathodes and control electrodes are connected respectively to the output and control inputs of the pulse shaper 6.

 The energy storage device 7 contains a capacitor, one lining of which is connected to the input, and the other to the output of the energy storage device.

 The switching unit 8 contains two parallel-connected chains of thyristors, each of which includes two serially connected controlled thyristors 29, 30 and 31, 32, receiving anodes of the first two controlled thyristors 29 and 31 are connected to the information input of the block, the first and second inputs of which are the cathodes of the first controlled thyristors 29, 31, respectively, of the first and second chains, the control inputs of the first controlled thyristor 29 of the first chain and the second controlled thyristor 32 of the second chain are connected to the control output of the clock generator and a first control unit are input, the second control input of which the control inputs are combined second controlled thyristor 30 of the first chain and the first controlled thyristor 31 of the second chain coupled to the second control output of the clock generator.

 When the device is turned on, the energy storage device 2 is charged to the voltage of the power source 1, starting thyristor 27, shunt thyristor 28, pumping thyristor 23, thyristor 22 of key 4 are closed, thyristors 29 and 32 are open, the capacitor 20 of key 4 is charged to the voltage of power source 1 through the circuit : output of power supply 1, charging inductor 16, diode 19, inductor 21, capacitor 20, limit resistor 9, open thyristor 29, primary winding of isolation transformer 10, open thyristor 32, common busbar of power supply 1.

 A four-channel master oscillator with four galvanically isolated outputs provides control pulses for the thyristor pulse shaper 6, key 4, and the delay time τ of the pulse of the fourth channel relative to the pulse of the second channel determines the duration of the output pulse at the load.

At the initial time t _about from the third channel of the master oscillator 14 opens the thyristor 23, then leads to the charge of the energy storage 7 through the inductor 24.

At time t ₁ , the thyristor 27 opens from the second channel of the master oscillator 14, then it leads to a gradual discharge of energy storage devices 2 and 7 through the limiting resistor 9, the open thyristor 29, and the primary winding of the isolation transformer 10 to the common bus of the power supply 1 through the open thyristor 32.

 The peak of the pulse decreases exponentially with a time constant equal to the product of the resistance of the limiting resistor 9, the primary winding of the isolation transformer 10 by the total capacity of the connected energy storage devices 2 and 7.

At the time t ₂ = t ₁ + τ from the fourth and first channels of the master oscillator 14, the shunt thyristor 28 of the shaper 6 and the thyristor 22 of the key 4 are opened, respectively (τ is the delay time of the control pulses of the thyristor 28 of the shaper 6 relative to the control pulse of the thyristor 22 of the key 4 determines the duration output pulse at the load). In this case, the energy storage device 7 is discharged through the open thyristor 28 of the shaper 6, the limiting resistor 9, the open thyristor 29, the primary winding of the isolation transformer 10, the open thyristor 32 to the common bus of the power supply 1 (Fig.2c - current through the primary winding of the isolation transformer).

 When you turn on the thyristor 22 of the key 4 in the LC circuit, the oscillation process begins (Fig.2d - voltage across the capacitor 20, Fig.2d - current of the oscillatory circuit of the key 4), through the thyristor 27 of the shaper 6 the total current of the oscillatory circuit of the key 4 and energy storage 2 flows , determined by the resistance of the limiting resistor 9, the primary winding of the isolation transformer 10.

When the maximum value of the current through the limiting resistor 9 is less than the amplitude of the current of the oscillatory circuit, the anode current of the thyristor 27 of the driver 6 at time t ₃ becomes equal to zero and goes into the circuit of the on-switching diode 18 (fig.2e - the current through the thyristor 27, fig.2zh - current through the oncoming commutation diode 18), then at the moment of anode current decay of the diode 19 to zero, the voltage at the switching capacitor 20 is restored and the discharge circuit of the energy storage device 2 is disconnected from the thyristor driver 6 pulses.

 Thyristor 28 serves to form the trailing edge of the pulse according to the exponential law and remains in the conducting state until the second energy storage device 7 is fully discharged to the load. In this case, a pulse decay is formed with a time constant equal to the product of the capacity of the energy storage device 7 and the resistance of the limiting resistor 9 and the primary winding of the isolation transformer 10, a pulse of positive polarity is formed at the output terminals 11.

The formation of a pulse of negative polarity at the output terminals 11 occurs after a time τ _g equal to twice the duration of the period of natural oscillations of the switching circuit.

 The control signals of the clock generator 15 are supplied to the switching unit 8 to the control inputs of the thyristors 30, 31, every second pulse of a given shape and duration passes through an open thyristor 31, the primary winding of an isolation transformer 10, an open thyristor 30 to a common bus of the power supply 1.

 Thus, pulses of positive and negative polarity are formed at the output terminals 11.

 To ensure reliable switching of the thyristor current, it is necessary that the period of natural oscillations of the key circuit 4 is three times the turn-on time of the thyristors, and the amplitude of the current of the oscillatory circuit is two times the maximum current through the resistance of the limiting resistor 9 and the primary winding of the isolation transformer 10.

 The delay between the supply of pulses from the outputs of the master oscillator 14 is discretely controlled and determines the duration of the forming pulse.

 Tests have shown the reliability of the action and the ability to simulate bipolar impulse noise of a given shape and duration, while there is practically no transient process.

 Using the proposed solution will allow testing the equipment for noise immunity and more accurately simulate a given interference pulse.

Claims (2)

 1. DEVICE FOR MODELING PULSE INTERFERENCE, containing the first and second power sources, the first energy storage device, the first controlled switch, pulse shaper, filter, limiting resistor, isolation transformer and master oscillator, the outputs of the first power source connected to the filter inputs, one of the output the busbar of which is connected to the terminals of the primary winding of the isolation transformer, the outputs of the second power source are connected to the inputs of the first energy storage device, one terminal of which is connected with the first output of the first controlled key and the first output of the pulse shaper, the control inputs of the pulse shaper and the first controlled key are connected to the first, second and third outputs of the master oscillator, respectively, the first output of the limiting resistor is connected to the second terminal of the first controlled key and the inputs of the pulse shaper, characterized in that a second controlled key, a second energy storage device, a smoothing diode, a clock generator and a switching unit, information in the path of which is connected to the second output of the limiting resistor, the first and second outputs of the switching unit are connected to the terminals of the secondary winding of the isolation transformer, the first output of the second controlled key is connected to the first output of the pulse shaper, the second output of which is connected to the second output of the second managed key directly and through the second drive energy is connected to another terminal of the first energy storage connected to the anode of the smoothing diode, the first and second control inputs of the block switching and outputs of the clock, the clock input of which is connected to the first output of the master oscillator, the cathode of the smoothing diode is connected to the first output of the first controlled key.  2. The device according to claim 1, characterized in that the switching unit contains two parallel-connected circuits, each of which includes two serially connected controlled thyristors, the anodes of the first two controlled thyristors are the information input of the block, the first and second outputs of which are the cathodes of the first controlled thyristors respectively, of the first and second chains, the control inputs of the first controlled thyristor of the first chain and the second controlled thyristor of the second chain are connected and are the first control m the input of the unit, the second control input of which is the combined control inputs of the second controlled thyristor of the first chain and the first controlled thyristor of the second chain.

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