DE2106406C3 - MeOptatz for measuring frequency-dependent parameters of an electrical device under test with different transmitter and receiver tuning frequencies - Google Patents

Description

The invention relates to a measuring station for measuring

ίο frequency-dependent parameters of an electrical Test object, for example a four-pole, with a test transmitter feeding the test object and an output signal of the test object evaluating test receiver as well as with two generators, the independent Voting the test transmitter and the test receiver supply control voltages to them, their Frequencies during limited measuring times can each be set to two by means of a programmer different values (recipient tax rate

-ο and transmitter control frequency) are kept precise.

Such measuring stations find multiple applications in carrier frequency technology, e.g. B. in measurements across converters, when measuring harmonics (distortion factor measurements) or intermodular

^ i tion measurements.

Known measuring stations of this type have the disadvantage that they have two to generate the control voltages programmable b «: w. need controllable precision generators from a programmer that

in are very complex.

The invention is based on the object, in the case of measuring stations of the type mentioned at the outset, with only one controllable precision generator (adjustable by a programmer).

)> The invention solves this problem with the means disclosed in the characterizing part of claim 1. This saves a controllable precision generator and a simple frequency controllable one (lockable) oscillator with a frequency

Mi gel arrangement replaced.

A further development of the invention for measuring a test object with the simultaneous use of more than two control frequencies results with the apparent in the characterizing part of claim 2-

4 '. th means. This also brings you with only a single controllable precision generator. An embodiment of the invention which is particularly useful when the bandwidth of the device under test is greater than the bandwidth of the test receiver,

in results when the precision generator has the or a Transmitter control frequency supplies. A moderate drift of the frequency-controllable oscillator controlling the receiver in this case only has an effect corresponding to the slight ripple of the receiver pass-through

i) rich enough.

Any interfering frequency gaps that occur between the measurement times can thus be avoided, that all control frequencies are supplied by frequency-controllable oscillators that cyclically

Mi can be set by a precision generator that is cyclically set to the control frequencies by the programmer.

A locking of the frequency-controllable oscillator to a predetermined control frequency is carried out according to el

μ ner further embodiment of the invention with the Means of claim 5 facilitated.

The invention is shown schematically in the drawing using two exemplary embodiments. It

Fig. 1 is a block diagram of a first embodiment of a measuring station for measuring the Distortion attenuation of a device under test, and

Fig. 2 is a block diagram of a second embodiment a measuring station for measuring modulation products and image frequencies one with two frequencies powered mixer.

In the first embodiment, a measuring transmitter 1 feeds a test object 2, the output of which is at a Measuring receiver 3 with display instrument 4 is located. The measuring transmitter 1 and the measuring receiver 2 are via a Line 5 connected directly to one another for the transmission of a superimposition frequency. The measuring transmitter 1 is from a controllable precision generator 6, and the measuring receiver 3 is from a frequency-controllable oscillator IG each supplied with a control frequency for tuning.

The controllable precision generator 6 is connected to a common programmer via control lines 7 8 connected. Its exit is at a switchover contact an electronic switch 9, one of which has a fixed contact with the control frequency input of the measuring transmitter 1 and its other fixed contact with an input of a frequency-controllable Oscillator 10 associated phase discriminator 11 is connected. The latter feeds a control voltage store 12 of relatively large capacitance, the voltage of which is fed to a capacitance diode 13 is, which, together with an adjustable frequency preset capacitor 14, the frequency of the Oscillator 10 is determined. The use of the frequency preset capacitor 14 enables expansion the capture range of the frequency control and increases the stability of the controlled frequency of the oscillator 10. The capture range in regulating the frequency of the oscillator 10 could also be used a search oscillator.

The programmer 8 controls the entire measuring process except via the control lines 7 via others Lines If, 16,17,18a and 18fe to the measuring transmitter 1 or to the measuring receiver 3 or to the switch 9 or to the frequency-controllable oscillator 10. A message line 19 also leads from the latter to the programmer 8.

The measurement sequence is stored on a punched tape, not shown, whose information is from a also not shown punch tape reader of the programmer 8 to signals on the corresponding control lines (7, 15 to 18) is converted. This results in a measurement sequence with the following Steps:

1. The P / ogrammgebei 8 represents the controllable Precision generator 6 via the control lines 7 to the harmonic des to be measured Test object 2 required tuning frequency of the test receiver 3 and simultaneously sets over the control line 17 switches the switch 9 to the one connected to the phase discriminator 11 Contact.

2. The programmer 8 supplies the frequency-controllable oscillator 10 via the control line 18a with the command to adjust (to initiate the frequency or phase lock) to the frequency offered by the precision generator 6, after which it emits a digital signal via the control line ISb which has the frequency preselection capacitor I »5. to a value that

ι ■>

corresponds to one of the tuning frequency approaching frequency calls, so that the beginning Frequency control only regulate the difference between the tuning frequency and this frequency level got to.

3. During the control time in 2. until the phase lock is completed, the frequency-controllable Oscillator 10 a »reader stop signal, which - via the message line 19 to the programmer 8 given - the further program sequence blocks until the oscillator 10 on the precision generator 6 frequency offered is locked in phase.

4. After the "reader stop" signal disappears, the control voltage store 12 holds the voltage u supplied by the phase discriminator 11 when it locks, and thus the frequency of the oscillator 10 (receiver tuning frequency). Now the programmer 8 switches the switch 9 over the control line 17 to the contact connected to the measuring transmitter 1 and at the same time sets the precision generator 6 to the tuning frequency of the measuring transmitter 1 (fundamental oscillation for the test object 2) via the control lines 7.

5. After waiting for the test object to settle in the programmer 8 releases the measuring transmitter 1 and receiver via the control lines 15 and 16 2 for measurement.

6. After delivery of a measurement signal A new measuring cycle with a new harmonic begins via the control lines 15 and 16 of the device under test as the receiver tuning frequency in a new step 1.

The second embodiment differs from the first in that the test item - a mixer - two input voltages are required, and that two output signals of different frequencies (modulation product and image frequency) can be measured simultaneously. There are two measuring transmitters accordingly

21 and 22 each connected to an input of the mixer 23 to be measured and two measuring receivers 24 and 25 connected to its output. A test transmitter and a test receiver each also have a direct connection via a transmission frequency line. The measuring receivers each contain a display instrument 24a, 25a and are just like the second measuring transmitter

22 each acted upon by a frequency-controllable oscillator 26 or 29 or 32, which is constructed in the same way is, like the frequency-controllable oscillator in Fig. 1, so each, inter alia. a phase discriminator 27 or 30 or 33, furthermore a capacitance diode and one as Capacitor executed large control voltage store 28 or 31 or 34 contains.

A central programmer 35 is connected via control lines 37 with Ainet ¹ controllable precision generator 36 further includes a Wirklsitung 38 to a control input of an electronic switch 39, via control lines 40 and 41 to control inputs of Meide lighter 21,22 or sensing receivers 24, 25 and also via message and control lines 42,43,44 with den.frequency controllable oscillators 26, 29, 32. The changeover contact of the electronic switch 39 is at the output of the precision generator 36, the first fixed contact of the switch is connected to a control frequency input of the first measuring transmitter 21, the second fixed contact with the second measuring transmitter 22 and the third

or fourth fixed contact with the first and second measuring receivers 24 and 25, respectively.

The programmer 35 based on the information The measuring sequence controlled by a perforated tape is as follows:

1. The programmer 35 provides the controllable precision generator 36 via the control lines 37 to the tuning frequency of the first one required for the modulation product to be measured Measuring receiver 24 and at the same time provides the electronic via the active line 38 Changeover switch 39 to the third fixed contact, the one with the first frequency-controllable oscillator 26 associated phase discriminator 27 is connected.

2. The programmer delivers via the message and control line 43 to the first frequency-controllable Oscillator 26 the command to initiate the

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1 IVf ^ UVlU- L / Z.TT. 1 I1U31 «1I1 UOlUIIg UUI UlV TUJlI I IU" cision generator 36 offered tuning frequency, after it has configured the frequency preselection capacitor of the oscillator 26 via a digital signal to a capacitance value that gives the oscillator 26 a presetting to a frequency level approaching the tuning frequency.

During the control time until the phase lock is completed, the frequency-controllable oscillator gives 26 a "reader stop" signal via the message and control line 43 to the programmer 35, the the further program sequence is blocked until the oscillator 26 responds to that from the precision generator 36 offered frequency is locked in phase. On the latter, it is through the control voltage memory 28 recorded.

3. After the »reader stop signal has disappeared, the programmer 36 switches over the active line 38 continue to switch 39, and steps 1 and 2 are repeated with the second Measuring receiver 25 and frequency-controllable oscillator 29, the reporting and control line 42 and the phase discriminator 30: these steps are then repeated with the second Measuring transmitter 22, the third frequency-controllable oscillator 32, the message and control line 44 and the phase discriminator 33, always with the tuning frequencies required in each case.

4. After the last »reader stop signal has disappeared, the programmer 35 switches the switch 39 to the contact connected to the first measuring transmitter 21 and sets the PfäzisiöriSgenerator 36 to the tuning frequency of the first measuring transmitter 21 via the control lines 37.

j 5. After waiting for the settling time of the Mixer 23, the programmer 35 releases the measuring transmitter via the control lines 40 and 41 21 and 22 and receivers 24, 25 for measurement.

The control voltage stores 28, 31 and 34 are like this dimensioned that the set frequencies of the associated oscillators during the setting times and the measuring time remain sufficiently constant. This replaces the frequency-controllable oscillators 26, 29 υ and 32 practically three complex controllable precision generators in the manner of the precision generator 36.

For measurements with manual operation of the measuring

and a program automatically read by a programmer, it could happen that a Readjustment of the frequency-controllable oscillator is initiated by the operator only after a period of time, in which frequency has drifted away by a value that is impermissible for a given measurement accuracy is great. To avoid too long a time interval between two readjustments of the frequency of the frequency-dependent ' To avoid the oscillator with certainty, it is more practical to use "manual" measurements instead of

JO of the programmer to provide an additional automatic switch, velcher synchronized with a switch fulfilling the function of switch 9, the precision generator in periodic - possibly adjustable - alternating time intervals

Jj between two manually preset control frequencies switches the transmitter and receiver frequency.

For DUTs with long settling times, it may be unfavorable or impermissible if during the Adjustment of frequency-controllable oscillators the transmission frequency of a measuring transmitter is interrupted. In such a case it would be easily possible to fill the frequency gap with the help of another frequency-controllable oscillator, its phase discriminator with another changeover switch contact connected to bridge. This oscillator should then be in front of the oscillator or oscillators on the The receiver side can be adjusted and, if necessary, it could be more precise again during the measurement be readjusted.

1 sheet of drawings

Claims (4)

Patent claims: 1. Measuring station for measuring frequency-dependent parameters of an electrical test item, for Example of a quadrupole, with a test transmitter feeding the test item and an output signal of the test object evaluating test receiver as well as with two generators, the independent Voting the test transmitter and the test receiver supply control frequencies to them that during limited measuring times to two different ones which can be set by means of a programmer Values (receiver control frequency or transmitter control frequency) are kept precise, characterized in that only one of the two generators (6, 10) is a known, from a programmer (8) adjustable precision generator (6) and the other of the two generators is only one frequency-controllable oscillator (10), the output frequency of which with a skid of a frequency control voltage, the one Frequency control arrangement is generated, which has a frequency and / or phase comparator (Ils and a large control voltage store (12) to hold of the regulated frequency, to a regulation time before the Meözeit at a control input of the comparator (11) supplied by the precision generator (6) and set by the programmer (8) a certain frequency and then held on this becomes, nd that the programmer (8) the precision generator (β "» during "d the control time on sets a first of the two control frequencies and sets the output of the precision generator to the The control input of the comparator * (11) switches over to a second of the two during the measuring time Sets control frequencies and the output of the precision generator directly to the measuring transmitter or test receiver switches through. 2. Measuring station according to claim 1 for measuring a test item with simultaneous use of more than two control frequencies, characterized in that for generating each additional control frequency a further frequency-controllable oscillator (26, 29, 32) with a frequency control arrangement (27,28; 30, 31; 33, 34) and one further control time each are provided and that the programmer (35) the precision generator (36) during each of the control times and the measuring time to one tunes other of the various control frequencies and the output of the precision generator (36) during the measuring time directly to one of the measuring transmitters (21) or measuring receivers and during each of the control times with the control input of one of the frequency control arrangements (27, 28; 30, 31; 33, 34) of the frequency-controllable oscillators (26, 29, 32) connects. 3. Measuring station according to claim 1 or 2, characterized in that the precision generator (6) one or the transmitter control frequency (s) supplies. 4. Measuring station according to claim 1 or 2, characterized in that all control frequencies supplied by frequency control ports oscillators which are set cyclically by a precision generator, which is set cyclically by the programmer is adjusted to the control frequencies. 5- measuring station according to claim 1, thereby germinated draws that the frequency controllable. Oscillator one that can be controlled or triggered by the programmer Frequency preset (14),