RU2450430C1 - Method for shaping of single nanosecond and subnanosecond pulses and device for its implementation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device contains insulator, moving contact, stationary contacts one of which is purposed for connection with load while the other is connected to common contact; at that moving contact is made in the form of globe with diameter 30-40 times less than insulator length; insulator is made in the form of tube with stationary contacts at its ends; connection of one stationary contact with common contact is made by current lead with zero potential; globe is installed inside tube and it can move along its inner surface from one stationary contact to the other one.

EFFECT: possibility of pulse generation with nanosecond and subnanosecond duration, simplification of structure.

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Description

This invention relates to a pulse technique and can be used to test measuring instruments, to control the temporal characteristics of high-speed oscillographic equipment, as well as to verify distortion of signals in cable lines.

The challenge facing the technical field and the invention is aimed at is the creation of a method and device for generating single subnanosecond pulses for checking the hardware function of the oscilloscope, as well as for checking distortion of signals in cable lines.

Known similar methods and devices aimed at solving this problem.

For example, a device for generating subnanosecond pulses [patent RU 2206175, IPC H03K 3/53, authors: Nikiforov MG, Baldygin V.A.], and a method for generating pulses that can be carried out using this device. The method includes charging the forming line (PL) using an external electric power source, then quickly charging the output PL from the PL through two surge arresters and two transmission lines (PL) to the load through the electric capacitance with the formation of a single subnanosecond pulse in the load using a cutting spark gap shunting the load.

The device for generating subnanosecond pulses includes an external source of electrical power, a pulse shaping system consisting of a PL, which is connected through two surge arresters, and two submarines with an output PL, and an electric power source, one of the submarines is connected to the load, zero potential of PL and PL are their bodies and are connected to each other.

The disadvantage of this method and device is the use of an external electric power source, which complicates the design of the entire device, as well as the difficulty in manufacturing and operation, requiring additional configuration and high cost of the main parts.

The closest analogue of the invention, which is selected as a prototype, is a device for generating single nano- and subnanosecond pulses, which allows you to implement a method of producing pulses of a specified duration [A.I. Aleksandrin, I.S. Samodelov. The generator of single nanosecond pulses with adjustable amplitude and duration // Instruments and experimental equipment, No. 4, 1976, p.142-144].

The method of generating single nano- and subnanosecond pulses includes generating electric unipolar pulses of the required duration (from 0.5 ns and above), further transferring them to the load when moving the movable contact and its electrical interaction with one of the fixed PL contacts and current collection during interaction moving contact with another fixed contact to a common contact. The interaction of the movable contact with both fixed contacts is carried out simultaneously by telescoping the sliding contact, constantly interacting with one of the fixed contacts, until it contacts another fixed contact. The movement is carried out by means of an electromagnet connected to an external power source. The required pulse duration is achieved by selecting the length of the PL.

The forming device comprises an external cable line charged from an external stabilized power source through decoupling resistance, a brass case, which is a common contact, in which an insulator with a movable contact is rigidly fixed in it, two fixed contacts placed from the ends of the case, one of which connected to the load, while the movable contact is made in the form of a telescopic connection of a cylindrical shape to simultaneously provide electrical connection with GOVERNMENTAL contacts. The housing and fixed contacts form a sealed chamber, which is filled with hydrogen to ensure erosion resistance of the contacts. The impedance of the device must be consistent with the impedance of the connected external cable line. One of the fixed contacts is connected to the load, which is the oscilloscope under test, and the other is connected via an external cable line, a power source, and an isolation resistance with a common contact.

The disadvantages of the prototype are:

- the presence of an external power source, leading to a complication in the manufacture and operation of the forming device, as well as dependence on the power system;

- the inability to obtain an output pulse with a duration of less than 0.5 ns, which leads to a limitation of the functionality associated with the verification of high-speed equipment;

- execution in the device for forming a movable contact in the form of a telescopic connection, which requires high precision in the manufacture;

- ensuring the sealing of the housing during assembly, which leads to complication.

The technical result of the method is to expand the functionality of the method (the ability to determine the characteristics of high-speed recording equipment and signal paths designed to work with pulses of nano- and subnanosecond duration) by obtaining pulses of shorter duration.

The technical result of the device is to simplify the design.

An additional technical result that can be obtained by using the inventive device is to increase profitability.

The specified technical result in the method of generating single nano- and subnanosecond pulses is achieved by the fact that the method includes, in addition to the features common to the prototype, namely: generating electric unipolar pulses of the required duration with transferring them to the load when moving the movable contact and its electrical interaction with one from the fixed contacts of the forming line and the current collector during the interaction of the movable contact with another fixed contact to a common contact, distinctive: the action of the movable and fixed contacts is carried out by alternately contacting the moving contact with the fixed, while moving the moving contact is carried out on the surface of the insulator, forming electrostatic charges on the surface of the moving contact, and the required pulse duration is achieved by selecting the electrical capacitance of the moving contact C from the following ratio: C≤ τ / Rnagr, where τ is the required pulse duration, Rnagr is the load impedance.

In addition, the movement is carried out under the action of gravity when changing the spatial position of the insulator, or using a pneumatic device.

The specified technical result in the device for generating single nano- and subnanosecond pulses is achieved by the fact that the device contains an insulator, fixed contacts, a movable contact in contact with the insulator, and with the possibility of interaction with fixed contacts, one of which is designed to connect to the load, and the other is connected to a common contact, while the movable contact is made in the form of a ball, the diameter of which is 30-40 times less than the length of the insulator, and the insulator is made in the form of a tube, at the ends of they have fixed contacts, and one of them is connected to a common contact by means of a current path with zero potential, and the ball is installed inside the tube, with the possibility of alternately moving along its inner surface from one fixed contact to another.

The influence of the distinguishing features of the patent formula of the method on the technical result.

The interaction of the movable and fixed contacts by alternately touching them reduces the electric capacitance of the forming device, which leads to the possibility of obtaining an output pulse duration below 0.5 ns.

The movement of the movable contact on the surface of the insulator, which forms electrostatic charges on the surface of the movable contact, makes it possible to exclude the use of an external power source, which allows to expand the field of use, and also simplifies the design and operation of the generator and reduces its cost.

Achieving the required pulse duration by selecting the electrical capacitance of the moving contact C from the relation: C≤τ / Rnagr, where τ is the required pulse duration, Rnag is the load impedance, allows you to generate a pulse with a duration of less than 0.5 ns.

The implementation of the movement of the movable contact under the action of gravity when changing the spatial position of the insulator can reduce the dimensions of the device and simplify the method of manufacture and maintenance.

The implementation of the movement of the movable contact using a pneumatic device allows you to automate the process of moving without the use of an electromagnet, which allows the method in areas where it is impossible to use electromagnetic fields.

The influence of the distinguishing features of the patent formula of the forming device on the technical result.

The implementation of the movable contact in the form of a ball eliminates its jamming during movement, which ensures the reliability of the device with ease of manufacture.

The use of a ball with a diameter of 30-40 times less than the length of the insulator makes it possible to obtain a pulse amplitude of up to several tens of volts without the use of an external electric power source with a small capacity of the moving contact, thereby simplifying the design and operation of the device. This ratio is established experimentally.

The design of the insulator in the form of a tube, at the ends of which fixed contacts are installed, allows the use of standard connectors at the ends of the insulator, which are easily replaced.

The connection of one of the fixed contacts with a common contact by means of a current path with zero potential simplifies the design compared to the prototype, since there is no need to use decoupling resistance and other elements, and also ensures the return of electric charge to the device, which increases the efficiency of the device.

The location of the ball inside the tube, with the possibility of alternately moving along its inner surface from one fixed contact to another, provides the production of static electricity, which allows you to do without an external source of electrical power.

Consider the implementation of the proposed method in the form of a device, the design of which is shown in Fig. 1, where 1 is an insulator, 2 is a movable contact, 3 is a fixed contact, 4 is a common contact, 5 is a load, 6 is a current path with zero potential. Figure 2 shows the shape of the output signal with a positive polarity, and figure 3 shows the waveform with a negative polarity, which are obtained by connecting a current path with zero potential to different ends of the device.

The device is an insulator made in the form of a hollow tube made of organic glass with a length of 10 cm, a movable contact is made in the form of a metal ball with a diameter of 3 mm, a current lead with zero potential 0.2 m long, two fixed contacts and a common contact are connectors of the SRG- type 50, the load of the device is a cable line two meters long and with a wave impedance of 50 Ohms.

A device for forming a single subnanosecond pulse works as follows. To obtain the output signal on a high-speed oscilloscope (not shown), connect the load 5 to one of the fixed contacts 3 and to the common contact 4, while to the other opposite fixed contact 3 connect the common contact 4 using a current conductor with zero potential 6. Then, to obtain electrostatic charge on the surface of the movable contact 2 provide its movement along the surface of the insulator 1 to the fixed contact 3 connected to the common contact 4, and return back to the opposite stationary contact 3. At this moment, an electric unipolar pulse is generated when the accumulated electrostatic charge flows from the movable contact 2 to the load 5, through the fixed contact 3. To receive the pulse again, only the last two operations are repeated. In order to receive a pulse of a different polarity in load 5, load 5 is switched to fixed contact 3, to which a current path with zero potential 6 is connected, and the current path with zero potential 6 is connected to fixed contact 3, to which load 5 is connected.

A design study was carried out at the enterprise and a workable generator was created. When registering oscillographic equipment with a bandwidth of 10 GHz, pulses of positive and negative polarity were obtained with a duration equal to the limit of the hardware resolution of 100 ps, measured by the pulse width at half maximum, while the signal amplitude was within 2–7 V. Currently, this generator It is actively used to check cable lines for signal distortions, as well as to control the temporal characteristics of high-speed oscillographic equipment.

Claims (4)

1. The method of forming a single nano- and subnanosecond pulses, including generating electric unipolar pulses of the required duration with transferring them to the load when moving the movable contact and its electrical interaction with one of the stationary contacts of the forming line and current collector when the mobile contact interacts with another fixed contact on the common contact, characterized in that the interaction of the movable and fixed contacts is carried out by alternately contacting movably contact with the fixed, while moving the movable contact is carried out on the surface of the insulator, forming electrostatic charges on the surface of the movable contact, and the required pulse duration is achieved by selecting the electrical capacitance of the movable contact C from the following ratio: C≤τ / Rnagr,
where τ is the required pulse duration,
Rnag - wave resistance of the load. 2. The method according to claim 1, characterized in that the movement of the movable contact is carried out under the action of gravity when the spatial position of the insulator changes. 3. The method according to claim 1, characterized in that the moving movable contact is carried out using a pneumatic device. 4. A device for generating single subnanosecond pulses, containing an insulator, fixed contacts, a movable contact in contact with the insulator, and with the possibility of interaction with fixed contacts, one of which is designed to connect to the load, and the other is connected to a common contact, characterized in that the movable contact is made in the shape of a ball, the diameter of which is 30-40 times less than the length of the insulator, and the insulator is made in the form of a tube, at the ends of which fixed contacts are installed, and the connection th ones with common contact effected by current lead at ground potential, wherein the ball is mounted inside the tube, with alternating movement on its inner surface from one stationary contact to another.

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