SU517161A1 - Electron-beam voltage to current converter - Google Patents

Description

I

The invention relates to electronic engineering, in particular to electron-beam devices for measuring voltage pulses of nanosecond duration.

Electron-beam converters of voltage difference into current (zero-bodies) are known, containing a cathode installed in a vacuum shell, located near an optically transparent window in the shell, accelerating, focusing and deflecting systems and an electron multiplier with an aperture at its entrance. .

Since a thermal cathode is used in the known converters, this does not effectively control the time of the appearance of the electron beam.

In order to reduce the inertia of the electron beam control, the cathode is made in the form of a semitransparent flat photoemitting layer, and a slit diaphragm movable in a plane parallel to the cathode plane is installed near the outer surface of the window in the transducer sheath.

The drawing shows the proposed differential voltage to current converter.

The converter consists of an additional slit diaphragm I, made in the form of a round plate, coaxial cylinder 2, in the signal end of which there is a slot, and on both sides of it there are slots for moving and fixing the diaphragm, vacuum shell with window 3, photocathode 4 focusing and accelerating systems 5, signaling vertical deflecting plates 6, supporting vertical deflecting plates 7, auxiliary vertical deflecting plates 8, horizontal deflecting plates of the sweep 9, the main slit diaphragm 10, toricity II-electron multiplier and a pulse light source 12. The additional slit diaphragm 2 and

The coaxial cylinder 2 (light and magick screen) form a mechanical system. The diaphragm I is fixed on the signal end of the cylinder so that its gap coincides with a slot in the end. The size of the rectangular slit corresponds to the slit size of the diaphragm 10, taking into account the scale of the transfer of the image and the size of the photoelectron beam. The diaphragm 1 can be displaced in the grooves of the end of the cylinder and along the slot and fixed in any direction. Cylinder 2 freely rotates around the optical axis of the transducer and is securely fixed in any position. At the exit end of the cylinder there is a hole for

output multiplier 11.

The Converter operates as follows.

The light signal passes through the slit of the diaphragm 1, the slot of the cylinder 2 and the window 3 of the vacuum shell onto the outer surface of the photocathode 4. A narrow electron beam formed by the focusing and deflecting systems 5 passes between the deflecting plates 6-9 and, in the absence of stresses on the plates, falls through the slit of the diaphragm 10 to the input of the multiplier 11.

The converter is tuned to the maximum output current with no voltages on the plates. The diaphragm 1 is displaced along the slit of the cylinder 2 and the cylinder is rotated until the beam passes exactly through the opening of the diaphragm 10. The positions of the diaphragm 1 and cylinder 2 are then fixed.

The presence of a photoemitter in the converter and an external diaphragm allows not

only reduce the inertia of the measurements, i.e., measure the amplitude of shorter voltages, but also investigate the shape of the pulses.

Claims (1)

Invention Formula The electron beam voltage to current converter containing installed in a vacuum shell, a cathode located near the optically transparent window in the shell, accelerating, focusing and deflecting systems and an electron multiplier, at the entrance of which a diaphragm with a hole is installed, characterized in that, in order to reduce the inertia of the electron beam control, the cathode is made a semitransparent flat photoemitting layer, and near the outer surface of the window a slit diaphragm is mounted, movable in a plane parallel to the plane of the cathode. 12