DE943365C - Equipment for quadrupole measurements using the Weissfloch node displacement method - Google Patents

Description

Equipment for quadrupole measurements using the Weißfloch nodal displacement method the The invention relates to a method and devices for quadrupole measurements according to the Weißfloch knot displacement method. The nodal displacement method is especially used for measuring in the field of centimeter and decimeter waves or balancing of quadrupoles of a general kind is used, the output of the to measuring quadrupole with a variable short-circuit line and its input with a measuring line fed by a transmitter is connected to which the voltage distribution through a lengthways. the measuring line displaceable scanning probe is determined.

If you change the effective length by moving the short circuit of the short-circuit line over half the measuring wavelength, the position shifts the nodes of the voltage distribution on the measuring line relative to the displacement the short circuit by a distance J 1, which can be measured and based on the selected measuring frequency or

Wavelength immediately draws a conclusion about the properties of the quadrupole allows.

The hitherto usual execution of the nodal displacement method has the disadvantage that the measurement of the distance d 1 is relatively cumbersome and the reading accuracy depends on the accuracy of the minimum determination, those with with increasing wavelength also decreases. In addition the further disadvantage that fluctuations in the operating voltages cause measurement errors can.

There are also measuring devices for performing two-pole and four-pole measurements known with two probes arranged at a distance of A / 4 (cf. British patent specification 6I4259). In these known measuring devices, the ratio of the sum and the difference the voltage tapped at any point on the line by a quotient meter brought to the display, so it does not depend on the location of the node. -The invention relates to the method for four-pole measurements according to the Weißflochschen Nodal displacement method in which the output of the quadrupole to be measured with a changeable short-circuit line and its input with one fed by a transmitter Measuring line is connected to which the voltage distribution by a along the measuring line displaceable scanning probe is determined.

This method is applied according to the invention in such a way that the measuring line by at least two in a fixed, sized against A / small Scanned and mutually displaceable electrode probes arranged at a distance Determining the nodal displacement d 1 is the ratio of that scanned by the two probes Tensions is measured.

The invention thus enables the shift zl 1 to be determined by a ratio measurement and by a quotient meter for display which can be directly calibrated in values of D 1. This will on the one hand, the measurement is simplified so that it can, for. B. Easily and quickly in test bays is feasible. -On the other hand, the fluctuations in the operating voltages resulting errors largely avoided.

Furthermore, the invention has devices for the subject, which a allow automatic execution of such measurements, as well as devices which make it possible to determine the voltage curve along the measuring line on which the measurement is based to make visible on the fluorescent screen of a cathode ray tube.

The invention also extends to mechanical construction and the arrangement of the measuring line or its scanning device.

Further details and advantages of the invention emerge from the following description based on the drawing.

Fig. I shows a schematic representation of the measuring arrangement according to of the invention, Fig. In the voltage curve on the short-circuit line or measuring line in the arrangement according to Fig. I, Fig. 2 is a perspective view of the mechanical Structure of the probe drive and the associated measuring line, Fig. 3 one in the Cross-section through the device shown in Fig. 2, guided at the level of a scanning probe, Fig. 4 is a schematic circuit diagram for the control circuit for the probe drive used electric motor.

According to Fig. I, K is the one with a sliding short-circuit bridge k equipped short-circuit or dummy line and L is the measuring line on which the voltage curve is determined. Between the dummy line K and the measuring line L is in itself known way the test object M, which in particular by a quadrupole arbitrary Kind is made on. The measuring line L is from a measuring transmitter S via an attenuator D, which helps stabilize the input voltage, is fed.

Two solid lines are used for capacitive scanning of the measuring line L Distance 2r (of e.g. Io mm) arranged electrodes E1, E2 along the line L displaceable and mechanically rigidly connected to the short-circuit bridge k of the line K or are coupled by a synchronization control.

The line K and the line L have the same wave impedance Z, and the line lengths 1i and 12 are set so that when one is switched on DUT M the voltage curve on the measuring line L a node in the center between the scanning electrodes, so that that of the scanning electrodes E1 and E2 tapped voltages 061 and b2 have the same size. Going to happen now the short circuit on line K and the pair of probes on the line at the same time Z shifted so the junction of the spauning course on the line is shifted L shift relative to the sampling point by a distance zl I, so that the voltage curve assumes an asymmetrical position to the scanning electrodes E1, E2, as shown in Fig. 1 a is indicated.

The voltages e and 562 tapped off by the scanning electrodes are therefore unequal in size, and it can be shown that the ratio Q = f 62 of these two voltages by a simple relationship with the nodal point displacement d I is linked. With a good approximation r.Al r + dl and therefore d I = r f- Q where with r. denotes half the spacing of the scanning electrodes, which is a given one Represents the constant of the measuring device.

It follows that by measuring the ratio Q = X: 2 immediately the nodal shift d 1 and from this z. B. the four-pole error can be determined can.

The ratio Q: 2 can be displayed using a quotient meter Qm be brought, which is expediently directly calibrated in values of S 1, The The measurement result obtained in this way is evidently within wide limits of the fluctuations of the Measuring line feeding input voltage independent.

According to a further embodiment of the invention, for the display a cross-coil measuring mechanism commonly used for quotient measurements, whose Measuring windings the voltages picked up by the scanning electrodes after rectification are fed. An overlay shift drive to application come, in an appropriate way that the measuring voltages «1 and M62 each have one Mixer Mil or Mi2 are fed, which also to a common oscillator O are connected (Fig. I). The intermediate frequency voltages generated in these two mixer stages are each fed to an intermediate frequency amplifier Z1F or Z2F and then after Rectification sent into the measuring windings of the quotient measuring mechanism. The Andes Rectified voltages occurring at the outputs of the two intermediate frequency amplifiers, which are proportional to the measuring voltages 561 or v2 can be obtained by additional measuring devices or displayed on the fluorescent screen of a cathode ray tube. It is advisable to provide the option of using one of the two ZF-R amplifiers switch off and thereby the measuring system otherwise set up for quadrupole measurements to convert it into one for two-pole measurements.

To display the measurement result, instead of or in addition to the quotient measuring unit a cathode ray tube can also be used, the deflection devices of which have a control voltage, which is proportional to the movement of the pair of probes E1-E2, or one to the measured one Ratio Q = U 2 proportional control voltage is supplied. The longitudinal movement of the carriage carrying this pair of probes hardly, for example, with the aid of a Resistance slide track, with the help of a rotary resistance connected to the drive spindle this carriage is coupled, or by a photoelectric device or be converted into a corresponding control voltage by other means, the controls the deflection of the cathode ray in the horizontal axis. The control in the vertical direction can for example be effected by arr a rotating mirror is attached to the measuring mechanism of the quotient meter, with the help of which a photoelectric transmission proportional to the deflection angle of the measuring mechanism Control voltage is generated.

Since the longitudinal movement of the carriage carrying the pair of probes and the short circuit of the dummy line coupled to this in speed is limited, a fluorescent screen with a very useful for the cathode ray tube strong afterglow used. For example, if the slide movement is controlled that the distance of half a wavelength in a time of about 0.5 to 2 seconds is covered, the afterglow time of the tube should also be of this order of magnitude lie.

If certain points of the test lead are in the one on the fluorescent screen If you want to mark the oscillogram that appears, you can have one or more contacts provide that are actuated by the carriage as it moves and the fade-in effect of dark spots at the relevant points on the sled run.

The short-circuit bridge of the dummy line K is also with a Longitudinal guide, e.g. B. an actuated by means of a spindle slide guide moved.

The common drive of the short-circuit bridge and the scanning probe can done by hand or by a motor and is expediently on the carriage of the Electrode probes act, their movement in this case with the slide guide the short-circuit bridge is coupled by a suitable transmission. The transfer can by mechanical gear, by a flexible shaft, by electrical or hydraulic control or similar means can be carried out. However, one can also separate for the carriage of the line L and for the carriage of the line K Provide drive motors and these through a synchronization control or in another Sync way. In all cases one will - provide appropriate facilities. around the two carriages independently of one another and, if necessary, by hand to be able to move.

The motorized drive of the slide is expedient with automatic Reversing equipped by, for example, in the path of the probe carriage the line L attaches adjustable limit contacts that of the slide operated at either end of its trajectory to reverse and open the engine in this way, the carriage automatically moves back and forth on its set path To perform float.

As a drive can according to a further embodiment of the invention a collector motor can be used in the control circuit according to Fig. 4. After this The collector motor m is arranged in series with a grid-controlled electron tube R connected to a DC voltage source, the control grid of the tube at the adjustable tap of a voltage divider connected to this voltage source p or in the anode circuit of a control tube connected upstream of the tube R. The field winding w of the motor can, as shown in Fig. 4, in series with the armature of the motor rn are switched. However, it is also a circuit with separate excitation of the winding w applicable. With r 'is a protective resistance to limit any occurring Lattice current referred to. The direction of rotation of the motor is controlled by a switch s reversed, which reverses the polarity of the field winding w.

The. control circuit described has the advantage that by setting of the voltage divider p the speed of the motor m from standstill softly and sensitively can be regulated to the desired value, which is within wide limits of the mechanical Load on the motor remains independent and constant.

The mechanical structure of the measuring line L and the associated slide guide for the scanning electrodes is illustrated in one embodiment in FIGS. The measuring line labeled L is a concentric line with a prismatic one Outer shape formed and provided at both ends with connecting means of the usual type.

The line L is on a vertical surface of the bed B on the the probe carriage SL is guided, releasably attached, for example by means of light screwed on accessible screws. On one and the same slide guide you can So different measuring lines, concentric lines or waveguides with any Wave resistors and shapes can be screwed on or replaced. For example can be a waveguide for 3 cm wavelength or such up to 15 cm shaft length can be screwed on. All measuring lines intended for this purpose has in common that the scanning probes in the horizontal position in the longitudinal slot Sz immerse on the wall facing the slide guide.

The carriage SL supporting the scanning electrodes Et and E2 is turned on the bed B in the manner known from lathes by means of a prismatic guide and optionally guided as flat as possible with the help of support rollers and guided by a spindle SP in Driven longitudinally. The SL slide engages with a nose which the scanning electrodes E1 and E2 enter the measuring line, into the longitudinal slot Sz a. It will advantageously be ensured that the high-frequency connection represents as perfect a short circuit as possible between the measuring line and the slide. . This is achieved according to a further embodiment of the invention in that on the point at which the nose of the carriage enters the line slot Sz, the slide moves on a sliding surface of the bed, so it is very easy complete galvanic-capacitive short circuit is formed. The immersion depth of the probe electrodes is adjustable.

Finally, a schematically indicated is expediently indicated on the slide SL Reading microscope AM attached, which is on a fixed, illuminated from behind Moved along glass scale G, which can be divided into l / lo or l / loo mm. The scale G, for its part, can be used to determine the zero length using a micrometer drive with 1/100 mm graduation be adjustable in the longitudinal direction. With the help of this reading device one can at the described device, if necessary, the nodal point shift d 1 with very can be read directly with high accuracy and thus also the device (after releasing the coupling between the carriage of the short-circuit line or

Measuring line) for measurements according to the usual node displacement method use. You can either switch off one scanning electrode, so that only one scanning electrode is used (as has been the case up to now), or you can work in the manner described above with a pair of probes, where the nodal shift is measured by shifting the slide SL the sampled voltages and b2 to the same size, i.e. H. the rash of the Quotient meter Qm to 1: I (middle).

Finally, one can also use the one bearing of the drive spindle SP in Store longitudinally displaceable so that it is together with the spindle by means of a Micrometer drive for fine adjustment of the slide position by small distances can be moved in the axial direction. One is thereby able to during the automatic scanning of the measuring line a defined longitudinal displacement of the To be able to run the carriage opposite the middle node position, z. B. to to calibrate or check the display device.

The structure of the measuring line described with reference to Figs. 2 and 3 is not only for the measurements described above, but also for other measurements advantageous in which the voltage curve is scanned on a measuring line.

PATENT APPEAL: I. Method for quadrupole measurements according to the Weissfiochschen Nodal displacement method in which the output of the four-oil to be measured with a changeable short-circuit line and its input with one fed by a transmitter Measuring line is connected to which the voltage distribution by a along the measuring line displaceable scanning probe is determined, characterized in that; that the test lead by at least two spaced at a fixed distance of about 1/4 small, jointly displaceable electrode probes scanned and used to determine the nodal displacement (i11) the ratio (Q) of the voltages sensed by both probes measured will.

Claims (1)

2. Arrangement for carrying out the method according to claim I, characterized characterized in that the scanning electrodes (E1, E2) of the measuring line (L) with the movable Short circuit (K) of the dummy line (K) mechanically rigidly connected or by a synchronization control are coupled. 3. The method according to claim I, characterized in that the of voltages tapped off the scanning electrodes by a superimposition method in the frequency converted and after rectification each one measuring winding of a cross-coil measuring mechanism are fed. 4. The method according to claim 3, characterized in that the of The voltages tapped from the scanning electrodes are each fed to a mixer stage, which are connected to a common oscillator. 5. The method according to claim I, 3 and 4, characterized in that a cathode ray tube is used for display, the beam in one axis by a control voltage proportional to the scanning movement and in the other Axis deflected by a control voltage proportional to the measured ratio (Q) will. 6. The method according to claim 5, characterized by the use a strongly afterglowing screen of the cathode ray tube. 7. Arrangement according to claim 2 ,. characterized in that the drive takes place by an electric motor, which by in the movement path of the slide guide attached limiting contacts is automatically reversed. -8th. Arrangement according to Claim 2 or 7, characterized in that a drive is used. Collector motor (noun) serves whose armature in series with a grid-controlled electron tube (R) a DC voltage source is connected, and that the control grid of the tube at the adjustable tap of a voltage divider connected to this voltage source (p) or in the anode circuit of a control tube connected upstream of the tube (R), 9. Arrangement according to Claim 8, characterized in that the field winding (w) is in series is connected to the armature of the motor. Io. Arrangement for carrying out the method according to claim I or following, characterized in that the prismatic in the outer shape Measuring line (L) on a vertical surface of the bed guiding the probe carriage is releasably and easily interchangeable attached and on their the slide guide facing surface has a longitudinal slot into which the scanning probe can be inserted horizontally Immerse yourself in the location. II. Arrangement according to claim I0, characterized in that the Slide carrying scanning electrodes into the longitudinal slot of the measuring line with a Engages nose through which the scanning electrodes (E1, E2) enter. 12. Arrangement according to claim 10 and 11, characterized in that at the point where the nose of the carriage enters the longitudinal slot of the measuring line occurs, the carriage moves on a sliding surface of its bed to to form a very perfect galvanic-capacitive short circuit. 13. Arrangement according to claim 2,7 and following, characterized in that that for the direct determination of the node displacement on the slide a reading device, z. B. a microscope (AM) is provided, which is on a fixed scale moved along. 14. Arrangement according to claim 2, 7 and following, characterized in that that the drive of the carriage of the scanning probes is carried out by a spindle whose Fixed bearing can be moved in the axial direction for adjustment purposes by small distances is. References: French Patent No. 937 524; British Patent Nos. 584 250, 6I4 259; Magazine for techn. Physics, Vol. 24 (1943), p. 22; My. "Measuring devices and measuring methods for decimeter waves" (1949), P. 58; Montgomery: "Technique of Microware Measurements", McGraw-Hill Verlag (1947), 5. 8I6.