Tag Archives: crt

The oscilloscope tube

At the beginning of my blog, I talked about a small project with an oscilloscope tube. Since there are still pictures in the archive, I do not want to withhold it from the blog here:

Cathode ray tube with high voltage generation

A cathode tube (Braun tube) consists of an evacuated glass bulb in which a hot cathode of tungsten wire is heated by an electric heating wire. The electrons emerge from the surface as a charge cloud (annealing emission). Between the positively charged anode and the hot cathode there is an electric field in which the electrons are accelerated. A pinhole allows the approaching electrons to pass only a bundle of determinable diameter, the actual electron beam. The electron beam can then be further accelerated.
The Braun tube – as it is e.g. is present in a cathode ray oscilloscope – has two capacitor plates each to deflect the electron beam. (X and Y baffles). The tube is a Philips B7S 401 oscilloscope tube. For the sake of completeness, I list some technical data here:
  • Indirectly heated cathode, heating voltage Uf = 6,3V
  • Heating current If = 90mA 
  • time for heating kathode tK =1min
  • total accelerationvoltage Ua= 1,2kV
  • Base point tension of the post-acceleration resistance Ug5 = 300V 
  • acceleration voltage Ug4 = 300
  • focusing deltaUg3 = 20V … 50V
  • pre acceleration volatage Ug2 = 1,2kV
  • reverse voltage Ug1 = -30V … -80V
Connections on the tube socket

The aim of the project was therefore to put the small tube back into operation and to lure her a few pictures. So a drive had to be built. Since the supply voltages are quite varied (6.3V to 1200V), this problem had to be solved first. With a NE555, a few components and an old transformer (240 / 12V) a high-voltage power supply was tinkered.
The principle is simple: A DC voltage is switched on and off very quickly with a small circuit. This switched DC voltage in turn connects with a power transistor, the output side of the transformer. (ie where normally the 12V are applied now fed) The ratio of the transformer works in the other direction :). So arise at the exit ever a few hundred volts. (depending on the switching frequency). In order to produce over 1200V, I have connected a cascade (capacitors and diodes). (Functionality)
So now all voltages necessary for the operation of the tube are available to produce an electron beam. With the aid of adjustable voltage dividers, the beam current and the grids for brightness and image focus can be set.

the fist illuminated spot

The voltages for the baffles are also taken from the high voltage supply and controlled by transistors. Thus, a deflection of the electron beam in both axes is possible.

Plexiglas housing

The transistors in turn are controlled by a small pre-stage, which is fed externally with a voltage of -5V to + 5V – the control voltage for the deflection of the light spot. This control voltage input exists for both axes. I added another input to switch the electron beam to “bare”, ie dark. For this purpose, a corresponding voltage is applied to the corresponding grid, which previously block the electron current to the anode.


Thus, the tube can now be controlled directly from the outside, for example, by means of analog outputs of microcontrollers (Arduino, PIC, etc.) or NI DAQ cards with the extra-low voltages available there. After the first positive test runs with the breadboard electronics I then constructed a clean board and mounted the whole construction on a wooden board and covered with a transparent Plexiglas housing.
All connections are routed via banana sockets to the outside. For example, you can easily draw Lissajous figures on the screen …

Lissajous-figure done withe NI-DAQ
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The 80s and the Watchman

In 1985, the company Sony brings a small, compact and above all mobile TV on the market. The Watchman Voyager FD20-AEB. It has been designed to be used everywhere. For example, in the car, on vacation, just everywhere.
It is not a TV with LC display, or TFT, or LED display. No. The TV brings the image by means of a cathode ray tube (Braun tube) to the eye of the beholder. And not in the brilliant color variety and resolution of today’s receivers, but in black and white (BW).



The screen diagonal of 4.7 cm can be displayed with the help of a clip-on magnifier still a little enlarged.
The receiver is a multinorm receiver that covered the European television standards.

It was tuned manually by means of a side-mounted “rotary wheel”. The reception tapes VHF / UHF can be selected with a slide switch. Of course, only analog TV reception is possible.

source drawing: Frank’s Taschenfernseher.de




Settings such as brightness, contrast and also the image capture can be carried out on the underside of the device.

 Tunermodule and flattube

The power supply comes from four 1.5 volt AA batteries or from a power supply. At a power consumption of 2 watts is relatively fast on battery operation. The high voltage generation and heating of the flat screen tube is probably one of the biggest consumers of electricity.

The structure of the boards is very discreet. There are hardly any integrated circuits. The large tuner module can be seen on the left in the picture. The supply of signals takes place exclusively via a telescopic rod antenna. A built-in speaker provides the sound. Optionally, a jack for connecting a headphone is installed.

today there is only more noise to be received
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