Power Supply Unit (PSU): Difference between revisions

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[[File:Psu_and_core.png|Modern PSU (left) and Core (right) |alt=|thumb|300x300px]]
The power supply unit (PSU) converts low voltage supplied by the battery of the housing (commonly between 2 and 12V, depending on the unit) into the high voltage required by the tube (up to 60 kV for cascade designs). In most formats, the power supply is integrated into the image intensifier tube, with the housing simply supplying battery voltage directly.
The power supply unit (PSU) converts low voltage supplied by the battery of the housing (commonly between 2 and 12V, depending on the unit) into the high voltage required by the tube (up to 60 kV for cascade designs). In most formats, the power supply is integrated into the image intensifier tube, with the housing simply supplying battery voltage directly.


Most PSUs are a two stage design with a lower voltage part (often 2kv) with all the control logic in one stage and the  high voltage stage which creates the necessary voltage for the [[Phosphor Screen|phosphor screen]]. With older designs each stage is often a seperate component.
Most PSUs are a two stage design with a lower voltage part (often 2kv) with all the control logic in one stage and the  high voltage stage which creates the necessary voltage for the [[Phosphor Screen|phosphor screen]]. With older designs each stage is often a seperate component.


 
The logic inside the first stage is responsible for functions like automatic brightness control, bright source protection, gating or manual gain. all those functions use the same detection mechanism: They measure the current to either the [[Phosphor Screen|phosphor screen]] or the [[Microchannel Plate (MCP)|MCP]], if these currents exceed a certain limit the respective function is triggered.
The logic inside the first stage is responsible for functions like automatic brightness control, bright source protection, gating or manual gain.


=== Automatic brightness control ===
=== Automatic brightness control ===
Automatic brightness control is a feature which controls the gain according to the brightness over the whole image. The messurement is often done via measuring the current consumption of the photocathode and controls either the voltage of the phosphorscreen (in case of Gen 0 or 1) or the voltage across the MCP (in case of Gen2 or above). Automatic brightness control was first used on larger devices for vehicles or crew served weapons in the late 1960s.
Automatic brightness control is a feature which controls the gain according to the brightness over the whole image. This is usually determined by measuring the current consumption of the photocathode. It controls either the voltage of the phosphorscreen (in case of Gen. 0 or 1) or the voltage across the MCP (in case of Gen. 2 or above). Automatic brightness control was first used on larger devices for vehicles or crew served weapons in the late 1960s.


=== Brightsource protection ===
=== Bright source protection ===
Brightsource protection is aimed to protect the tube against bright flashes and strong lights. If the current flow inside the tube is great enough the BSP shuts the Unit down.  
Bright source protection is aimed to protect the tube against bright flashes and strong lights. If the current flow inside the tube is great enough the BSP shuts the unit down.  


=== Gating ===
=== Gating ===
Gating is a function where the photocathode is switched between a working and a non working state.  
Gating is a feature where the photocathode is switched between an operative and an inoperative state.  
 
In the working state the photocathode has a negative potential of around -200V compared to the MCP input side or in case of a gated Gen 0 or 1 tube a focus ring.
 
And around +50V in the non working state. This positive potential causes the electrons (created by the photocathode) to get accelerated backwards to the Photocatode.
 
 
There are 2 variants of gating,  a manual gating and a auto gating:


In the manual gating, the tube switches between both state according a Input signal. This method is often used for scientific purposes, like ultra high-speed photography.
In the operative state the photocathode has a negative potential of around -200V compared to the MCP input side (or in case of a gated Gen 0 or 1 the tube a focus ring).  


The second and more common method is autogating. The tube switches automatically, according to the brightness of image, between both states with a high frequency. The aim is to get a better contrast in mixed (urban) light conditions.
In the inoperative state the potential is around +50V. This positive potential causes the electrons (created by the photocathode) to get accelerated backwards to the photocatode.  


=== Manual gain ===
There are two variants of gating, manual gating and autogating:
Manual gain is a feature where the user can lower the Gain with a potentiometer. There commonly 2 diferent tube formats that can have manual gain:


==== MX-10160 ====
During manual gating, the tube switches between both states according to an input signal. This method is often used for scientific purposes, like ultra high-speed photography.
Here Only the 3 pin variations have manual gain. The gain is normally adjusted via a 50kΩ resistor between the middle and the right negative pin. The gain is antilogarithmic toe the resistance, that means that the piggest gain is achieved when the middle pin is shorted to ground.


==== MX-11769 ====
The second and more common method is autogating. The tube switches automatically, according to the brightness of the image, between both states with high frequency. The aim is to get better contrast in mixed (urban) light conditions.
The gain is controlled via a potentiometer of around 180kΩ between the pins of the pigtail.


[[Category:Technology]]
[[Category:Technology]]

Latest revision as of 11:18, 3 August 2023

Modern PSU (left) and Core (right)

The power supply unit (PSU) converts low voltage supplied by the battery of the housing (commonly between 2 and 12V, depending on the unit) into the high voltage required by the tube (up to 60 kV for cascade designs). In most formats, the power supply is integrated into the image intensifier tube, with the housing simply supplying battery voltage directly.

Most PSUs are a two stage design with a lower voltage part (often 2kv) with all the control logic in one stage and the high voltage stage which creates the necessary voltage for the phosphor screen. With older designs each stage is often a seperate component.

The logic inside the first stage is responsible for functions like automatic brightness control, bright source protection, gating or manual gain. all those functions use the same detection mechanism: They measure the current to either the phosphor screen or the MCP, if these currents exceed a certain limit the respective function is triggered.

Automatic brightness control[edit | edit source]

Automatic brightness control is a feature which controls the gain according to the brightness over the whole image. This is usually determined by measuring the current consumption of the photocathode. It controls either the voltage of the phosphorscreen (in case of Gen. 0 or 1) or the voltage across the MCP (in case of Gen. 2 or above). Automatic brightness control was first used on larger devices for vehicles or crew served weapons in the late 1960s.

Bright source protection[edit | edit source]

Bright source protection is aimed to protect the tube against bright flashes and strong lights. If the current flow inside the tube is great enough the BSP shuts the unit down.

Gating[edit | edit source]

Gating is a feature where the photocathode is switched between an operative and an inoperative state.

In the operative state the photocathode has a negative potential of around -200V compared to the MCP input side (or in case of a gated Gen 0 or 1 the tube a focus ring).

In the inoperative state the potential is around +50V. This positive potential causes the electrons (created by the photocathode) to get accelerated backwards to the photocatode.

There are two variants of gating, manual gating and autogating:

During manual gating, the tube switches between both states according to an input signal. This method is often used for scientific purposes, like ultra high-speed photography.

The second and more common method is autogating. The tube switches automatically, according to the brightness of the image, between both states with high frequency. The aim is to get better contrast in mixed (urban) light conditions.