DE2511055C2 - CIRCUIT ARRANGEMENT FOR DETERMINING TRANSMISSION PROPERTIES OF A FOUR-POLE - Google Patents

Description

The invention relates to a circuit arrangement for determining transmission properties a quadrupole, consisting of a first oscillator, which reacts to the harmonics of a basic quartz frequency adjustable and lockable, a second oscillator that is within one of the frequency spacing between adjacent harmonics corresponding frequency range continuously adjustable and on the respectively set frequency is stabilized, a circuit part that consists of both oscillator voltages derives a measuring voltage by mixing and feeds it to the four-pole input, one with the four-pole output connectable superimposition receiver, in which the measuring voltage derived via the quadrupole with the voltage of a third oscillator, which is the first oscillator with respect to the adjustable wedge: and Latchability corresponds to, and the voltage of a fourth oscillator that is related to the second oscillator corresponds to the continuous adjustability and stabilization, in a constant intermediate frequency position is implemented, and from a downstream device for evaluating the implemented and through an intermediate frequency band pass filter guided measurement chipining.

The stabilization of the second (fourth) oscillator, whose output frequency is continuously adjustable, serves to improve its frequency error, which without this stabilization would be in the order of magnitude of 10 " ^{3 of} its output frequency, while the frequency error of the first (third) oscillator in the locked state also without special temperature constancy is only in the order of magnitude of 1Ü ~ ^{5 of} its output frequency. The importance of the stabilization measures is therefore greater, the higher the frequencies emitted by the second (fourth) oscillator. The rasterization of the first and third oscillator and the simultaneous stabilization of the The second and fourth oscillators enable a highly selective determination of the transmission properties of the quadrupole by means of an extremely narrow-band dimensioning of the intermediate frequency bandpass filter for crosstalk attenuation measurements, non-linearity measurements.

5 or the like takes place, the influence of interference voltages largely switched off on the measurement. This in turn ensures the implementation of such Measurements without loss of accuracy even with small and very small four-pole output voltages,

3i ° so z. B. with very large damping measurement values, such as they occur within or on the edge of filter blocking areas.

A circuit arrangement of the type mentioned is known from DT-PS 10 76 265. the

The stabilization of the second oscillator consists in the fact that its output voltage is converted into the much lower frequency position of a first interpolation oscillator by mixing it with a frequency-stabilized auxiliary voltage and is readjusted to the value of the respectively set frequency of the first interpolation oscillator by means of a control circuit. If the starting frequency of the second oscillator by at least a factor of 10 ^etc. down and selects the frequency position of the first Interpolationsoszillators correspondingly low, then the second oscillator with the aid of the first Interpolationsoszillators can be adjusted as accurately despite a continuous frequency variation, as if each individual value of its output frequency would be controlled by a quartz crystal. The fourth oscillator is stabilized in an analogous manner by means of a second interpolation oscillator. An adjustment scale on the first oscillator is used for the coarse measurement frequency setting, one on the first interpolation oscillator for fine adjustment, while a further adjustment scale on the third oscillator is used for the coarse display of the reception frequency selected in the heterodyne receiver and an adjustment scale on the second interpolation oscillator provides the corresponding fine display.

In particular, due to the stabilization measures mentioned, there is a circuit outlay for this known arrangement, however, very large.

The invention is based on the object, in a measuring arrangement of the type mentioned at the outset a very high selectivity with a much lower one To achieve circuit complexity than before. This is done according to the invention in that the second and fourth oscillator each contain a quartz oscillator, the frequencies on each one Fixed frequency stabilized, and with the help of Jusiiereinricluungen. which shift the fixed frequencies in relation to them very small justicrbcrcichcn, are designed to be continuously adjustable in their frequencies that the frequency spacing between the two neighboring harmonics (irr crystal fundamental frequency is chosen so small. that it does not exceed the width of the adjustment range of the fixed frequencies, and that a display of the frequency of the measuring voltage

gender, the first and second oscillator or the measuring voltage deriving first and one indicating the tuning frequency of the heterodyne receiver, the third and fourth oscillator downstream, second frequency counter are provided.

The invention is based on the knowledge that the use of frequency counters !! a much more accurate one Setting the first and third oscillator to the individual Raststcllen allows than this has been the case so far. Therefore, the basic crystal frequencies or the frequency spacings can be determined for both oscillators Reduce adjacent harmonics so much that the second and fourth oscillator do this despite a quartz stabilization to a fixed frequency in each case with the aid of only relatively small shifts the adjusting device (pulling device) permitting fixed frequency, each with continuously adjustable Interpolate intermediate values.

The advantage that can be achieved with the invention is, in particular, that the high selectivity is essential Requires simpler stabilization measures on the second and fourth oscillator than before. In particular fall the first and second interpolation oscillator and the output frequencies of the second and converting the fourth oscillator into the frequency positions of the first and second interpolation oscillators Circuit parts of the known arrangement from DT-PS 10 76 265 now gone.

In order to continuously adjust the frequencies of the second and fourth oscillator in a simple manner can, their adjustment devices according to a development of the invention each consist of one Voltage-controlled capacitance, in particular capacitance diode, arranged in the frequency-determining circuit which is connected to an adjustable voltage source.

The invention is described below with reference to a few preferred exemplary embodiments shown in the drawing explained in more detail. It shows

F i g. 1 shows a first embodiment and its modification to a synchronized measuring arrangement, which represents the second embodiment,

F i g. 2 a third embodiment,

F i g. 3 special training of the evaluation device and the

F i g. 4, 5 and 6 designs of the quadrupole adapted to special measuring tasks.

In the circuit arrangement according to FIG. 1, a first oscillator 1 and a second oscillator 2 are provided, the output frequencies / I and / 2 of which are fed to a mixer 3. A mixed product formed in this, e.g. B. the voltage with the difference frequency is fed through a filter 4, an output amplifier 5 and an output voltage divider 6 to a circuit point 7 and represents the measurement voltage Um with the frequency fm .

The oscillator 1 is designed as a so-called raster oscillator, which can be adjusted and locked to any desired harmonic of a quartz basic frequency supplied by a quartz-stabilized oscillator 8. For this purpose / “is fed to a harmonic generator 9, which _{emits a large number of harmonics / n} , 2 · / _n ... Η · I _n to a phase detector 10. When the frequency / 1 is sufficiently close to each of the harmonics, this provides an alternating voltage, which is fed to a frequency control input 12 of the oscillator 1 via a low-pass filter 11 and changes its frequency / 1 until it is applied to the respective harmonic of the basic quartz frequency / ₍₎ is set. Once this setting has been reached, the phase detector 10 generates a direct voltage Ur, which depends on the phase difference between the constant input voltages supplied to it. Ur serves as a control voltage, which counteracts any deviation from the attained setting and thus from the selected harmonic and thus ensures that the oscillator 1 "locks" on the relevant harmonic. With a correspondingly large number of harmonics of / ₀ , it is possible to cover a large frequency range with / I.

The frequency / 2 of the oscillator 2 is continuously adjustable within a second frequency range, which corresponds in size to _{the basic crystal frequency / n} or the distance between two adjacent harmonics of / _0. A stabilization of the

ίο each set frequency / 2 comes in the Way comes about that a quartz crystal 13 indicated by 14, frequency-determining circle on a Fixed frequency stabilized and that the latter with the help of an adjusting device, which is shown in

Exemplary embodiment consists of a controllable capacitance diode 15, which is shifted in an adjustment range which is very small in relation to it. The frequency setting of / 2 is expediently carried out by means of a potentiometer 16 which is fed by a direct voltage source 17. Each adjustment of the potentiometer 16 causes a change in the control voltage Ust, which influences the capacitance of the diode 15 and thus the respective value of / 2. The adjusting device, which is also referred to as a pulling device, can generally consist of a capacitive or inductive reactance arrangement which can be set to different reactance values by means of a control voltage.

However, a prerequisite for continuous adjustability of the measuring frequency fm is that the frequency spacing between adjacent harmonics controlling the oscillator 1 is chosen so small that it does not exceed the width of the adjustment range of the fixed frequency of the oscillator 2. A frequency counter 18, which counts the measuring frequency fm , offers an exact and therefore unambiguous one. Possibility of setting the oscillator 1 to individual locking points, which is necessary for this. Appropriately is

the counter 18 is directly influenced by the output voltages of the oscillators 1 and 2, one of the two oscillator frequencies, e.g. B. / 2, gate pulses are derived and used to open a gate circuit 19, via which the oscillations of the other oscillator, z. B. 1, in 18 are counted. On the other hand, it is of course also possible to count the oscillations of the frequency fm in the counter 18 during a predetermined counting time.

The measuring voltage Um occurring at the circuit point 7 of the continuously adjustable frequency fm is fed to the input of a quadrupole 20, the transmission properties of which are to be determined. For this purpose, the quadrupole

20 derived measurement voltage Um ' with the frequency fm', which is available at the switching point 21, is fed to a high-frequency superimposition receiver, which is followed by an evaluation device A

is switched. The frequencies fm and fm ' at the input and output of the quadrupole 20 are generally the same, but can also differ from one another, e.g. B. in a DUT with frequency converting properties or in non-linearity measurements.

The heterodyne receiver has in detail an adjustable voltage divider 22, which is followed by a low-pass filter 23 and a first conversion socket 24. A third oscillator 25, which can be set to various equidistant frequency values / 3 for the purpose of coarse tuning. supplies the conversion stage 24 with a voltage U 3 which converts the measurement voltage Um ' or a part thereof derived in 22 into a first IF band ZFB1 . This is done by mixing Um ' and U 3 in 24 and the subsequent screening out of a mixed product I / _Zfl through a downstream bandpass filter 26 which defines the pass band ZFB1. The mixed product U _ZF j arrives at a second conversion stage 27, in which it is converted into a second intermediate frequency band ZFB 2 , which is achieved by mixing it with a voltage U 4 supplied by an oscillator 28 and by subsequently filtering out a mixed product U _{ZF 2 by} means of a Bandpass filter 29 happens, which defines the Durch'.aßbereich ZFB 2. The frequency / 4 of the voltage U 4 can be continuously adjusted for the purpose of fine-tuning the heterodyne receiver within a frequency band corresponding to the distance between two adjacent frequency values / 3. The voltage U _ZFs is finally converted in a further conversion stage 30 by mixing with the voltage t / 5 of a fixed frequency oscillator 31 and by subsequently filtering out a mixed product U _ZF3 by means of a bandpass filter 32 into a third intermediate frequency band ZFB 3.

After previous amplification in an intermediate frequency amplifier 33, UZF 3 is fed to the input EA of an evaluation device A which determines the desired transmission properties of the quadrupole 20 from various parameters of the selected voltage Um '. Individual circuit configurations of the evaluation device A are described in more detail below in connection with special measurement tasks.

The oscillator 25, like the oscillator 1, is designed as a raster oscillator which can be set and locked to any desired harmonic of a basic quartz frequency / "" supplied by a quartz-stabilized oscillator 34. For this purpose / ₀ 'is fed to a harmonic generator 35, which outputs a plurality of harmonics / ₀ ', 2 · / "'... π · / ₀ ' to a phase detector 36. When the frequency / 3 approaches each of the harmonics sufficiently, this delivers an alternating voltage which is fed to a frequency control input 38 of the oscillator 25 via a low-pass filter 37 and changes its frequency / 3 until it is applied to the respective harmonic of the basic crystal frequency / "" is set. Once this setting has been reached, the phase detector 36 generates a direct voltage Ur ' which depends on the phase difference between the input voltages of the same frequency fed to it. Ur ' serves as a control voltage, which counteracts any deviation from the attained setting and thus from the selected ¹ Pn harmonic cn and thus ensures that the oscillator 25 "locks" on the relevant harmonic. With a correspondingly large number of harmonics of / ₀ ', it is possible to cover a large frequency range with / 3.

The frequency / 4 of the oscillator 28 is continuously adjustable within a second frequency range, that of the basic crystal frequency / "'or the distance between two adjacent harmonics of /"' corresponds in size. A high level of accuracy and

ίο Constancy of the continuous setting of / 4 comes about in such a way that an oscillating crystal 39 determines the frequency indicated by 40 Circle stabilized at a fixed frequency and that the latter with the help of an adjusting device, which in the illustrated embodiment consists of a controllable capacitance diode 41, in a ratio is moved to her very small adjustment range. The frequency setting of / 4 takes place expediently by means of a potentiometer 42,

ao that is fed by a DC voltage source 43. Each adjustment of the potentiometer 42 causes a change in the control voltage USt ', which affects the capacitance of the diode 41 and thus the respective value of / 4. The adjustment device,

as which is also referred to as a pulling device, can generally consist of a capacitive or inductive reactance arrangement, which by means of a control voltage can be set to different reactance values.

The prerequisite for continuous tunability of the heterodyne receiver is that the frequency spacing between adjacent harmonics of / ₀ 'is selected so small that it does not exceed the width of the adjustment range of the fixed frequency of the oscillator 28. A frequency counter 44, which counts the measuring frequency fm ' selected on the basis of the respective tuning, offers a precise and thus unambiguous setting possibility of the oscillator 25 to individual detent points, which is required for this. Appropriately, the counter 44 is directly influenced by the Atisgangsispannungen the oscillators 25 and 28, one of the two oscillator frequencies, z. B. / 4, gate pulses are derived and used to open a gate circuit 45, via which the oscillations of the other oscillator frequency, for example / 3, are then counted into 4Ί. A constant counting amount corresponding to the center frequency of the intermediate frequency band ZFB 2 is deducted from the counting result obtained in this way, which indicates the frequency difference between / 2 and / 4.

The engagement of the oscillators 1 and 25 au harmonics of the quartz fundamental frequency / "or / ₀ 'unc the stabilization of the oscillators described \ and 28 entails, on the one hand the measuring frequency fm at 1 and 16 is set very accurately and with Drosse constancy and can be read on the counter 18 with high resolution and that, on the other hand, the heterodyne receiver can be tuned to any desired frequency fm ' with great accuracy and constancy, with fm' then being readable on counter 44 with high resolution. However, this also means that the respectively selected frequency fm ', which corresponds to the set measuring frequency fn or is dependent on it in a certain way, after the implementation in stages 24 and 2'

709 617/39

25 Π

is transposed with great accuracy and constancy to the center frequency of the second IF band ZtBl and, if necessary, after a further conversion into a third IF voltage U ₁ , _{Λ can be filtered out} by an extremely narrow-band intermediate frequency bandpass filter 32. This high selectivity of the heterodyne receiver, which allows to eliminate numerous interfering influences during the measurement, is permissible because the further measurement errors that could arise from a possible uncontrolled transfer of the voltage Uχι , ₃ from its frequency setpoint, are practically insignificant due to the stabilization measures.

The individual harmonics of / ₀ lie in the middle of what are known as capture ranges, the width of which in each case corresponds to approximately twice the limit frequency of the low-pass filter 11. The latching of the oscillator 1 onto a harmonic occurs when the associated catchment area is reached. On the other hand, a holding area is assigned to each harmonic, and when it is left, the latching is canceled again. Between each holding area and the adjacent capture areas, there are frequency ranges in which there is no latching. It is useful to provide a display device (indicator lamp) 46 which, for example, depending on the disappearance of the alternating voltage component occurring at the frequency control input 12, indicates the respective latching of the oscillator 1 * reach or even partially overlap. In this case, the display device

⁴ tSnt ^ "* * ^ ^^ above the frequency range to be swept by fm ' in such a way that the first intermediate frequency band ZFB 1 is also above the last-mentioned range to be dimensioned so that it lies above the highest frequency fm 'to be evaluated and below the frequency setting ranges of 25 and 28, whereby a special mirror-wave security is guaranteed.

A circuit arrangement according to FIG. 1 was carried out on a trial basis with the following frequency characteristics: The basic crystal frequency / was 1 kHz, with its between 24 MHz and 42 MHz Harmonics for the oscillator 1 were used as rest points. The oscillator 2 was made by the Schwingquan 13 stabilized to a frequency / 2 of 24 MHz and using the adjusting device 15 16 17 in the frequency The range from 23.999 MHz to 24 MHz is continuously adjustable. By forming a difference

ao of the frequencies / 1 and / 2 resulted in a continuously sweepable range of the measurement frequency fm from 1 kHz to 18 MHz.

, 5 waves controlled the oscillator 25 The oscillator 28 was finally stabilized by means of the quartz oscillator 39 to a frequency / 4 of 21 6 MHz and by means of the adjusting device 41 42 and 43 in the frequency range from Ή 599 MHz 'to 21 6 MH2

3c continuously adjustable 'so that the frequency fm' had a range from 1 kHz to 18 MHz. The I ₀ Ih'nd called η ζΐ ling values are only intended to serve as a further explanation of the circuit according to Fiel and limit the

If frequencies f _{m have} a particularly large long-term constancy, it can be. It may be expedient to significantly expand the holding areas assigned to the individual harmonics of / _{0 after the oscillator 1 has been set.} The latches, which are only canceled when you leave these extended holding areas, are then particularly stable. However, it is necessary here for the sake of clarity that z. B. to reduce largely overlapping, expanded hold areas during the frequency setting of the oscillator 1 to their normal width.

With regard to the capture and hold areas of the harmonics controlling the oscillator 25, / 'applies the same as for the harmonics of / ". Chop the display device, which shows the locked state of the oscillator 25, is designated by 47. If the holding areas are dimensioned accordingly, it can also be omitted. To achieve A large long-term constancy of the tuning of the heterodyne receiver can also continue to Hold ranges assigned to the individual harmonics of / "'after the oscillator has been set 25 can be expanded significantly.

In order to be able to cover a large relative frequency range with the measuring frequency fm , it is advisable to arrange the frequency setting ranges of the oscillators 1 and 2 above this range and to determine the measuring frequency fm from the Fre- / 1 H 11 Ah n; flFK; w u

"" fflf Γ ^ ΐ ^ Τΐ ^ object to be measured, z ^ ei ^ Fc ^ iSeSt ^ ¹ must be a bit of spatial expansion that the connection points 7 and 21 are at different points in ^ oSe «because they are divergent, ^especially "? J "'The setting inf d? pSSnz t "Sd dTe Abs imung on a FreauVn ·, w · TS"". other separated and Ll ^ ¹ ^ ^FallV0nem temporally ^ tg "egten egg

reason for a fairy side vl f ^! ^ h f η Λ

nungsper oner ^ fuf? "Ι ηΓ? , Si

the quadrupole 20 Idnrh κ "" u « ^Επΐρ ίΤ ⁵ · ^εΐ ί. ^ε ·] ·

SchaSS "St 7 and M ^ Ä 'location are so there is S ^ ^{location being} :

from

and the vote ?! Ϊ / '
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at the dfeEnS »^ ^P ί ^{Γ E. rfi} " ^dun g ^ei ! ^know

auf / ^ synch "ns _ert 1 ^^ ^ ^Ab - ^tim T ⁿⁱ leadership beisoiTl £ 1 ^m - ^{TO the} J ^w ^ ^te " £ ^υ ? Fig l ^ £ s _r i _che ht f "ί " * ^{eS required} ' ^ΙΓ the SchaltSnSte Ie 1 2 ίϋΆ ^ ™ ^zuiu Z ™ ^U "In the single series _e >t" Π ** ^^ f ^' line 48 from the AmLp HT · Sy ^nchr ° " ^isatl ° ^ni>

for / 1 intended EiL ^ ϊϊ ™ *. ²⁵ ™ ⁶ " ...: - _7_- ^g . ^En ™ ^en input of mixer 3 so

_q "e" z _ei " _s , eNb = rich _c der O ^ Ha.oren 25 _and " d 28

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25 Il 055 υ

11 12

chronisationsleitung -19 contains a Frequcnzumsetz- differs, the third by the fact that the shuttering means of a modulator 50 and a tungslei'.e _25> 28, 34 cease to 43 and 47 and ordered in nachgeschütteten bandpass filter 51 and the up their function through a synchronization line 61, the frequency / 4 of the oscillator 28 would be shifted from the output of the oscillator 1 to the amount pre-set for / 3, which corresponds to the middle frequency; '- 5 shy input of the conversion stage 24 as well as one of ZIB1 . To this; Purpose v is the further synchronization line 62, 62 'from the Aus-Moduk'.toi 50 an auxiliary frequency / _w supplied, which in the output of the oscillator 2 to the provided for / 4 a modulator 52 from the frequency j S and a; Input of the implementation stage 27 are replaced. The further auxiliary frequency f _{tll is} formed and a frequency bandpass filter 53 is filtered out by means of a synchronization line 62. /; /, is the preferred setting device, which consists of a modulator 63 and a harmonic of f ₀ ' and is made up of a downstream bandpass filter 64 and the oscillator 34 has the task of frequency / 2 of the oscillator via a frequency multiplier 54 2 to be derived. offset an amount equal to that of the center frequency

In the second exemplary embodiment according to FIG. 1, the intermediate frequency band ZFB2 corresponds. The voltage of the oscillator 25 is applied to the 15 for this purpose, the modulator 63 is supplied with an auxiliary point of the voltage of the oscillator 1 and the span frequency / _{; / 2} , which is supplied from the oscillator 8 via voltage of the oscillator 28 after the previous frequency - a frequency multiplier 65 is derived,
shift by the amount of the center frequency In the third embodiment according to FIG. 2 of ZFB 2 takes the place of the voltage of the oscillator so the voltage of the oscillator 1 takes the place of the lator 2. The counter 44 shows both the tuning 30 of the voltage U 3 of the oscillator 25 and the span frequency of the heterodyne receiver as well as the voltage of the oscillator 2 according to the previous frequency-each measuring frequency. Only in the case where shift by the amount of the center frequency of that between the frequencies and fm 'fm a con- ZFB2 in place of the voltage t / 4 of the oscillator frequency offset is stant gevmnscht, the expedient 28. The counter 18 shows both the Measurement frequency fm moderately by a frequency in the synchronization line 48 as as well as the respective tuning frequency fm 'of the overlaid, with a frequency multiplication receiver ap. Isi only for the case that the fan _55/0 of 'derived auxiliary frequency acted upon between the frequencies and fm fm' a constant estimated modulator 56 with a downstream band frequency offset is desired, the appropriate ball 56 "is generated, the counter 18 comes a by a meaning inherent in the synchronization line 61. 30 added, with one over a frequency multiplier

In the numerical example given above, 66 resulted in an auxiliary _{frequency derived from / 0}

In this connection, the following concrete modulator 67 with a downstream bandpass filter 67 π

Values: The center frequency of the second intermediate signal is generated, the counter 44 has its own

frequency band ZFB 2 was set at 2.4 MHz , meaning.

while the fixed frequency / 5 of the oscillator 31 35 The third embodiment described above

Was 2.3 MHz. To generate the auxiliary frequency, for example according to FIG. 2 is, however, interfering

fn, which also had to be 2.4 MHz, became due when the modulators generated in the modulator 63

Fixed frequency / 5 of 2.3 MHz with a frequency f _H , lation products through the band filter 64 only incompletely

of 100 kHz mixed in 52. to be constantly blocked and to some extent

The above-described second execution 40 enter the implementation stage 27. A further example according to FIG. 1 is, however, to the extent that disruptive elimination of these interfering influences is due, as the module produced in the modulator 50 is a preferred further development of the third filling product by the; Bandolier 51 only achieved an incomplete example, which consists of the fact that the circuit parts 28 and 39 to 41 of FIG. 1 get into mixing stage 3. A far-reaching function will remain. In addition, a phase detection circuit for these interfering influences is provided by a pre-gate 68 which, with one of its inputs, achieves the output of the oscillator 28 with one of its inputs and with its output, which consists in that the circuit output is via a low-pass filter 69 on the connecting parts 2, 13, 14 and 15 remain in function, with a point 70 between the potentiometer 42 phase detector 57 with one of its inputs to the 50 enabled capacitance diode 41 and the oscillating output of the oscillator 2 and its output quartz 39 is switched. In this development, the synchronization line 62 ' falls across a low-pass filter 58 to the fixed contact 59 and is switched by a changeover switch 60, which replaces a synchronization line 62 " in the dashed line, which places the capacitance diode 15 from the outlet of the bandpass filter 64 with the other input the handle of the potentiometer 16 is separated and for this it connects to the 55 of the phase detector 68. In this way it connects the output of the low-pass filter 58. In this way, the oscillator 28 is set to the respective value then the synchronization line via the synchronization line 62 "is omitted. transmitted 49 'and is readjusted and thus largely replaced by a synchronization line 49''frequency, which is synchronized to the other input of the phase change-free.

tector 57 is performed. In this way, the 60

Oscillator 2 to the respective value of the kens on the first and / or third oscillator

Synchronisationsleirwng 49 "transmitted frequency torl, 25 the switching causing the locking

readjusted and thus largely trouble-free syn- thesis parts switched ineffective and the named

chronized. Oscillators in their frequency for the purpose of on

F i g. 2 shows a third exemplary embodiment of the search for a specific frequency, which varies continuously

Invention, in which the vote on fm ' with the particular in the synchronized Schaltungsan Setting of fm is synchronized. Of which in order can also be a periodic frequency F i e. 1 shown, first embodiment un- variation by means of a frequency control input

12 'and 38' supplied to the frequency control voltage Ujst or V] st 'for performing a sweep measurement be provided, where ^d: e bandwidth of the intermediate frequency band-pass filter 32 because of the required short Einschv; ingzeiten must be increased in general.

In Fig. 3, various circuit configurations of the evaluation device A known per se are shown. For example, a rectifier 71 can be connected downstream of the input EA , which evaluates the amplitude of Um ' in the desired manner and outputs a direct voltage Ug via the output 72. This is supplied to or through the input 73 of an analog display device 74 after passing through an analog to digital converter 75 of a digital display device 76. If one wishes to 'measure the level of order in place of the voltage amplitude, an additional logarithmic encryptor 77 is required, also in 75 can be included. In wobble operation, the voltage Ug indicating the amplitude or the level of Um 'is fed via an input 78 of the vertical deflection device of a cathode ray oscilloscope 79, the horizontal deflection of which is acted upon by the voltage of a time deflection generator 80, which is supplied with the frequency control voltage Ujst or Ufst 'of the swept oscillators 1, 25 is synchronized. The time deflection generator 80 is omitted if the frequency control voltage Ufst or Ujst 'is supplied directly via an input 81. With an evaluation device / 4 designed in this way, attenuation measurements, crosstalk attenuation measurements, non-linearity measurements or the like are carried out on the quadrupole 20.

To measure a complex transfer rate of the quadrupole 20 Um ' two ring modulators 82, 83 are fed, which on the other hand are acted upon by the voltage Um supplied via an input 83 a, but in the case of the modulator 82 with a phase shift of 90 °, which is reflected in a phase shifter 84 is produced. The modulators 82, 83 then emit voltage components Um '■ sin φ and Um' · cos φ , where φ represents the phase angle between Um and Um ' . These stress components correspond to the imaginary and real parts of the complex transfer vector. If they are fed to the deflection systems of a cathode ray oscillograph 85, the vector sought can be represented graphically. If, on the other hand, the voltage components are fed individually to the input 78 of the vertical deflection device of 79 and the horizontal deflection device is controlled in wobble operation via the circuit part 80 or 81, its frequency-dependent curve courses result. Instead of the voltage Um , a reference voltage Ure j generated by a generator 86 and having the same frequency and phase as Um can also be used.

The phase angle of the quadrupole 20 is evaluated by means of a phase detector 87 to which Um ' and Um or Uref are applied and which supplies an output voltage Ug which represents a measure of the phase angle. This is again fed to the analog display device 74 or the digital display device 76 via the input 73. To measure the group delay of the quadrupole 20, the voltage Um is amplitude-modulated by means of a voltage Usp supplied via the modulation input 5 ', the voltage Um' derived via 20 being supplied to a demodulator 83? The wire demodulated voltage Usp 'is schließlic fed to a phase detector 89 which is acted upon by the scorching andererseit equalize through the terminal 89 a supplied Modula tion voltage Usp or with a frequency and PBA reference voltage Uref of a genera tors 90th 89 then emits a direct voltage Ug " , which represents a measure of the group delay time of the quadrupole 20. Ug" can also be fed to the input 73 and displayed in 74 or 76. Tensions Ug 'and Ug "can ande hand, the input supplied 78 de cathode ray 79 and ii the manner described as frequency curves Darge is also in the sweeping operation. Wiii you by the quadrupole 20 ai a sinusoidal measuring voltage Um hervorgeru fene fast Phasenstörmodulation (" Phase -Jitter «, the phase detector 87 is followed by a high pat 91 whose output voltage Ug" represents a measure for the interference modulation, while slow changes in the phase angle are below the cut-off frequency of 91 and are therefore not taken into account. The evaluation device can be single, multiple or contain all of the assemblies shown in FIG. 3, but this is not limited to the embodiments shown.

F i g. 4 shows a special embodiment of the quadrupole 20 which is suitable for measuring the reflection factor, the reflection attenuation or the error attenuation. Here, the circuit point 7 is connected to the primary winding 92 of a differential transformer, the divided secondary winding of which has a center tap 93 connected to ground. The secondary winding halves 94 and 95 form four bridge sides with a resistor Rx of unknown size and a reference resistor Rn , the bridge corner points 93 and 96 representing the four-pole output. The bridge corner point 96 is connected to the circuit point 21. In this case, the voltage Um ' represents a measure of the reflection factor indicating the mismatch between Rx and Rn , while the voltage level Um' measured on a logarithmic scale directly indicates the reflection attenuation given a suitable size of the transmission level Um. If the resistance Rn is the input impedance of a telecommunication line and Rx is the input impedance of an associated line simulation, this is also referred to as error attenuation.

F i g. 5 shows a preferred embodiment of the quadrupole 20 for measuring the asymmetry attenuation of a three-pole α, b, c. The node 7 is here

via a reference resistor - ^ - with which the primary

Coil halves 97 and 98 are connected separating center tap of a differential transformer. The winding ends of 97 and 98 are connected on the one hand to poles α and b of the symmetrically constructed three-pole, the third pole c of which is at ground potential E , and on the other hand to the connections of a reference resistor Z. The resistance between poles α and c is denoted by RaIc , the resistance between b and c mil RbIc. The secondary winding 99 of the differential transformer is connected to the circuit point 21 and to ground. In this circuit, the measured level represents

15th

Um 'represents a measure of the asymmetry attenuation a _u , which is defined in the following way:

a _u = 20 log

To To '

For the purpose of measuring the impedance, the quadrupole 20 is preferably used as shown in FIG. 6 trained / IO

det. Here, the circuit point 7 is connected to the primary winding 100 of a transformer, the secondary winding of which is in series with an impedance to be measured Rx ' and a normal resistance Rn . If the voltage Um is kept at a constant amplitude during this measurement, the current flowing through Rn and thus the voltage Um dropping across Rn represents a measure of the impedance of Rx ' .

For this - ^ sheet of drawings

Claims (14)

Patent claims: 1.Circuit arrangement for determining the transmission properties of a quadrupole, consisting of a first oscillator, which is adjustable and lockable to the harmonics of a basic crystal frequency, a second oscillator, which is continuously adjustable within a frequency range corresponding to the frequency spacing between adjacent harmonics and stabilizes at the respectively set frequency is, a circuit part that derives a measurement voltage from the two oscillator voltages by mixing and feeds it to the four-pole input, a superimposition receiver that can be connected to the four-pole output, in which the measured voltage derived via the four-pole is mixed with the voltage of a third oscillator, which is related to the first oscillator corresponds to the adjustability and latchability, and the voltage of a fourth oscillator, which corresponds to the second oscillator with regard to the continuous adjustability and stabilization, into a constant intermediate frequency nzlage is implemented, and from a downstream device for evaluating the converted measurement voltage passed through an intermediate frequency bandpass filter, characterized in that the second and fourth oscillators (2, 28) each contain a quartz oscillator (13, 39) which records their frequencies one fixed frequency each is stabilized, and with the help of adjusting devices (IS, 16,17; 41, 42, 43), which shift the fixed frequencies in adjustment ranges that are very small in relation to them, are designed to be continuously adjustable in their frequencies (/ 2, / 4) so that the frequency spacing between significant harmonics of the basic crystal frequency (/ ", / ₀ " ) is chosen so small that it does not exceed the width of the adjustment ranges of the fixed frequencies, and that the first (1) and second oscillator (2) or the measuring voltage (Um) indicating the frequency (fm) of the measuring voltage (Um) dissipative circuit part! (3 to 6) downstream, first (18) and a second frequency counter (44) that displays the tuning frequency (fm ') of the heterodyne receiver and that follows the third (25) and fourth oscillator (28). 2. Circuit arrangement according to claim 1, characterized in that the adjusting device from one in the frequency-determining circuit (14, 40) arranged, voltage-controlled Capacitance, in particular capacitance diode (15, 41), which is connected to an adjustable voltage source (16, 17; 42, 43). 3. Circuit arrangement according to claim 1 or 2, characterized in that of the first (1) and third oscillator (25) one connected to the output of the other by eir.e Synchronization line (48, 61) is replaced. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that from the second (2) and fourth oscillator (28) one through one to the output of the other switched synchronization line containing a frequency conversion device (50, 51; 63, 64) (49, 49 '; 62, 62') is replaced. 5. Circuit arrangement according to one of claims 1 to 3, characterized in that of the second (2) and fourth oscillator (28) the output of one (28, 2) via a one Frequency conversion device (50, 51; 63, 64) containing synchronization line (49, 49 "; 62, 62 ") and the output of the other (2.28) each to the inputs of a phase detector (57, 68) are connected, the output of which is connected to a frequency control input of the latter oscillator (2, 28) is connected. 6. Circuit arrangement according to claim 5, characterized in that the frequency control input with the terminals of the frequency-determining circuit (14, 40) of the second or fourth oscillator (2, 28) arranged by the adjustable voltage source (16, 17; 42, 43 ) preferably activated, voltage-controlled capacitance (15, ⁴ A) is connected. 7. Circuit arrangement according to claim 5 or 6, characterized in that the over the Synchronization line (49, 62) transmitted output voltage of the fourth or second oscillator (28, 2) in the frequency conversion device (50, 51; 63, 64) by means of one of the first or third oscillator (1, 25) controlling harmonics, possibly after a previous frequency shift the same, is implemented. 8. Circuit arrangement according to one of the preceding claims, characterized in that that the oscillations of the first and second oscillator (1, 2) the counting input of the first frequency counter (18) via a gate circuit (19), which during the Occurrence of a gate pulse derived from the voltage of the second or first oscillator (2, 1) is open. 9. Circuit arrangement according to one of the preceding claims, characterized in that the oscillations of the third or fourth oscillator (25, 28) are fed to the counting input of the second frequency counter (44) via a gate circuit (45), which during the occurrence of one of the Voltage of the fourth or third oscillator (28, 25) derived gate pulse is open, with a constant count corresponding to the center frequency of an intermediate frequency band (ZFB 2) that can be tapped on the output side by the conversion stages (24, 27), which is taken into account in the counting result . 10. Circuit arrangement according to one of the preceding claims, characterized in that that the individual locking points of the first and / or third oscillator (1, 25) assigned Holding areas are chosen so large that they are catching areas that are adjacent to the R ;. are assigned, reach or partially overlap. 11. Circuit arrangement according to one of the preceding claims, characterized in that that the individual locking points of the first and or third oscillator (1, 25) assigned Hall areas can optionally be significantly expanded. 12. Circuit arrangement according to one of the The previous claims, characterized in that the frequency setting ranges of all four oscillators (1, 2, 25, 28) as well as the first intermediate frequency band (ZFB1) of the heterodyne receiver obtained after the coarse tuning are above the frequency range of the measuring voltage (fm, fm ') . 13. Circuit arrangement according to one of claims 1 to 12, characterized in that with an extremely narrow band design of the IF bandpass filter (32) the converted measurement voltage (Vm) is evaluated with respect to its amplitude and / or phase. 14. Circuit arrangement according to one of the preceding claims, characterized in that that the first and / or the third oscillator (1, 25) after the ineffective switching of the ratcheting causing circuit parts (8 to 11; 34 to 37) in their frequency steadily and in particular are periodically variable (wobble) and that the pass band of the IF bandpass filter (32) is adapted to the wobble operation if necessary.