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1<?php
2        $seiten_id = 'messtechnik';
3        $version = '$Id: measurement.php 258 2012-05-28 16:06:24Z sven $';
4        $title = 'Measurement and Experimental technology';
5       
6        require "../../lib/technikum29.php";
7?>
8    <h2>Measurement and Experimental technology</h2>
9
10    <p>Measurement- and Experimental technology can link Communication and Computer
11       Technology. Measurement technology has a long history and there have been nice and
12       remarkable devices.</p>
13<!--
14    <p>Professionals can see many beautiful measurement devices, from the complex mirror galvanometer (a piece from the German Kaiserzeit) to the scintillation measuring station with counting devices from several epoches (since 1956), used for measurement of radioactivity.</p>
15-->
16
17    <div class="box left clear-after">
18         <img src="/shared/photos/kommunikationstechnik/experimente.jpg" alt="Some of the experimental physics devices" width="396" height="451" class="nomargin-bottom" />
19         <p class="bildtext">
20           This picture shows some devices from the "experimental physics" area. You
21           will probably note the use of "natural" materials (wood, glass, metal) and the
22           well-designed very simplified interface that makes comprehension simple.
23           <br/>We will go into detail for some of the devices shown on the left.
24       
25    </div>
26
27        <h3>Galvanometer</h3> <!-- sic -->
28       
29      <div class="box left clear-after">
30            <img src="/shared/photos/kommunikationstechnik/universalmessgeraet.jpg" alt="Fotografie des Universalmeßgerätes" width="396" height="325" />
31            <p class="bildtext">
32               This is a remarkably functional, big and beautiful all-purpose measurement device made by Siemens &amp; Halske (about 1905). At that time even simple objects of utulity were made lovely detailed. This device was used as auxiliary device for morsing purposes in the national administration of the German Empire.
33            </p>
34      </div>
35     
36      <div class="box left clear-after">
37        <img src="/shared/photos/kommunikationstechnik/h+b.galvanometer.jpg" alt="Foto eines Galvometers von Hartmann  Braun" width="400" height="351" />
38        <p class="bildtext">In 1891, this beautiful galvanometer was purchased from Hartmann & Braun (Frankfurt/Main, Germany) and offered in catalogs. The principle is simple: in the underlying coil (green) flows the current to be measured, which builds a magnetic field. In this field sits a very sensitive compass needle which is hung up on a thin wire. The longer and thinner the torsion wire, the more sensitive the device.<br>
39Measuring was then an art that had to be mastered. Particularly disturbs the Earth's magnetic field, so that a correct positioning were only able by experts.</p>
40    </div>
41
42      <div class="box left clear-after">
43           <img src="/shared/photos/kommunikationstechnik/h&amp;b-galvanometer.jpg" alt="Photography of a mirror galvanometer" width="396" height="436" />
44           <div class="bildtext">
45             <p>Until the invention of measurement amplifiers, measuring very small voltages
46             and currents was a big problem. To do that job, moving coil devices had to be
47             very sensitive. This was realized with a moving coil that was mounted on a
48             torsion wire. The reflecting mirror at the lower end of the wire was spotted by
49             a light ray, so the whole composition acts like a very long "light needle".
50             By this way very long needle lengths (multiple meters) could be simulated.
51             Such a galvanometer must be set up absolutely horizontally and vibration-free.
52             <br/>The <b>Mirror Galvanometer</b> by Hartmann&nbsp;&amp;&nbsp;Braun is
53             a simple and functional demonstration model from the 1920s.</p>
54           </div>
55    </div>
56       
57       
58        <h3>Radio engineering</h3>
59
60    <div class="box left clear-after">
61          <img src="/shared/photos/kommunikationstechnik/neva-funktechnik.jpg" alt="Photography of the Neva Experimental system" width="396" height="280" />
62          <p class="bildtext">With the <b>NEVA radio technology system</b>, students could
63            do challenging experiments like measuring the wave lengths in the VHF area
64            with the Lecher lines.
65          </p>
66    </div>
67       
68        <h3>Cathode Ray Tubes</h3>
69
70    <div class="box left clear-after">
71        <img src="/shared/photos/kommunikationstechnik/loewe-kathodenstrahl.jpg" alt="Photography of the cathode ray tube" width="396" height="189" />
72        <p class="bildtext">
73            At the time where there was no television and no oscilloscope yet, the
74            <b>Cathode Ray Tube</b> was a sensation, especially at school. This was one of
75            the very first experiments where students could see that electrons have
76            almost no inertia, so they can be deflected easily at the presence of an
77            electric field.
78            <br/>This tube (with power supply on the left) from the German company
79            <b>Loewe</b> is an historical piece from the 1930s. It measures about
80            50&nbsp;cm!
81        </p>
82   </div>
83
84
85    <!-- paragraph: AEG Oszi. Translated/Started at 28.07.08-->
86    <div class="box left clear-after">
87          <img src="/shared/photos/kommunikationstechnik/aeg-oszi.jpg" alt="Photography of an AEG oscilloscope" width="425" height="419" />
88                  <p class="bildtext">
89              After the currency reform in West Germany, the production
90              of mesurement devices got going again. This AEG
91              oscilloscope was built in 1949. It seems to be an exact
92              replica from an AEG device of the late thirties. It is
93              equipped with steel tubes that were put on the German
94              market at 1938. Neither the time base of the horizontal
95              deflection nor the amplitude of the vertical deflection
96              are callibrated by the manufacturer. To measure
97              absolutely with this device, you always need reference sizes.
98          </p>
99      </div>
100
101      <div class="box left clear-after">
102          <img src="/shared/photos/kommunikationstechnik/phywe-oszi.jpg" alt="Photography of a Phywe demonstration oscilloscope" width="396" height="269" />
103          <p class="bildtext">
104             The "Physikalischen Werkst&auml;tten" (<i>phsyical facilities</i>), <b>Phywe</b>,
105             have built this small oscilloscope for demonstration purposes that can be
106             used to show the electromagnetic interaction of an electron beam in E/B fields.
107             Since (CRT driven) television got a mass medium, these experiments
108             were state-of-art at those days.
109          </p>
110       </div>
111           
112
113
114   <h3 id="t555">TEKTRONIX Oszilloscopes</h3>
115        <div class="box left clear-after">
116        <img src="/shared/photos/kommunikationstechnik/tektronix555.jpg" alt="Tektronix 555" width="396" height="448" />
117                <p class="bildtext">
118                In the heyday of pulse technology as used in radar and computing the development of high performance oscilloscopes was necessary. This is where an Oregan based company named Tektronix Inc. made a name for themselves. Their products are examples of high precision measurement equipment showing great workmanship and extraordinary performance. In addition to that Tektronix oscilloscopes
119came with service manuals that are a joy to read and a source of knowledge in electronic circuit design. Over the years Tektronix oscilloscopes became the epitome of high quality commercial oscilloscopes nearly unrivaled by other companies.<br>
120On the left hand side the truly gigantic Tektronix Type 555 oscilloscope is shown. The oscilloscope sitting next to it is a Type 564 which is also quite big but does not compare with the 555.
121The Type 555 was first sold in 1963 and is a true dual-beam oscilloscope with two individual time bases. This makes it superior compared with traditional dual-channel oscilloscopes with only a single time base and an electronic chopper for the dual-channel display. <br>
122The 555 features a separate power supply which is sitting on the bottom of the oscilloscope cart (a scope mobile). All in all the 555 contains about 100 tubes - an extraordinary amount for such a device. As a result the power requirement of the 555 is quite high with about 1 kW.<br>
123The maximum signal frequency that can be displayed with the 555 is 33 MHz - an outstanding value for the time. Oscilloscopes like the 555 were normally carried from one place to another by a cart (it is next to impossible to lift such a device as a single person). Therefore the scope mobile often had storage space for additional modules that were not regularly used.<br>
124The 555 on display is in mint condition - a rare circumstance since most  oscilloscopes from this time show signs of their heavy duty use.<a  class="popup" href="/shared/photos/kommunikationstechnik/555.jpg"><b> A high resolution picture of the 555</b></a> can be seen here.</a><br>
125The Type 564 oscilloscope on the scope mobile on the right uses a bistable storage tube - a technology that was not mature at this time. These tubes were characterized by a short life time. Most notably the brightness of the display decreased rapidly with time and the maximum beam velocity for
126storing images was about 500 cm/ms.<br>
127Below the 564 is a Tektronix Type 453 - a small oscilloscope which is quite difficult to service and repair due to its small physical size. By the way: Modern Tektronix oscilloscopes offer bandwidths up to 80GHz!
128                </p>
129                </div>
130
131        <h3>Digital experience system</h3>
132       
133    <div class="box left clear-after">
134        <img src="/shared/photos/kommunikationstechnik/digitalexperimentiersystem.jpg" alt="photography of an electronic experimental system for use in schools" width="396" height="509" />
135        <p class="bildtext">This big white board is an experience system from
136          <b>Leybold</b> from the early 1970s. At that time, the subject
137          "digital electonics" was taught in the school. Students could set up
138          logic systems like binary counters, full adders, flip-flops, multiplexer,
139          etc. This was quite fascinating for students at that time. Today, in ordinary
140          schools, there is no more time for electronics in the curriculars.</p>
141    </div>
142       
143        <h3>The world of electronical calculating</h3> <!-- schleim... -->
144
145    <div class="box left clear-after">
146       <img src="/shared/photos/kommunikationstechnik/frequenzzaehler.jpg" alt="Photography of different frequency- and event counters" width="420" height="582" />
147       <p class="bildtext"><b>Calculating requires counting</b>
148         <br/>Last but not least we show a composition of (frequency) counters from
149         different epoches. There are, among others, devices equipped with tubes (57
150         electron tubes) or discrete transistor logic (mostly germanium).
151         The different counting tubes (e.g. E1T or GC10B) and the very different
152         display types are quite impressive.</p>
153    </div>
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