DE1033738B - Contact rectifier arrangement to be used for highest frequencies - Google Patents

Description

Contact rectifier arrangements to be used for highest frequencies The invention relates to contact rectifier arrangements to be used for highest frequencies, in particular also for wide frequency bands, in which the feed lines are designed to be coaxial. The practically point-like contact between the tip and the barrier layer of a rectifier represents a two-pole with very small geometrical dimensions. This point-like two-pole has known electrical characteristics; it acts as a consumer just like the parallel connection of a resistor with a capacitance. Common values of the rectifier types commercially available today are around 1 kü to 100 2 for resistance and around 0.3 to 0.4 pF for capacitance.

The high-frequency voltage must be the point-shaped rectifier path are supplied via feed lines. One would now like to achieve that the tension the input of the supply lines as little as possible from the voltage at the output, So at the rectifier path, differentiates. Furthermore, the input resistance should the supply line terminated with the rectifier line as real and frequency-independent as possible be.

To set up such a rectifier, it is advisable to use the supply lines run coaxially. Only then does the input resistance and voltage sensitivity become apparent clearly detectable. Coaxial embodiments of rectifiers are inherently in known to the most diverse species. But they all have the disadvantage that they only can be used up to the frequency range of a few, for example 4 GHz, and in addition, due to the contact resistance that is now present and the junction capacitance that has a detrimental effect is unsatisfactory in its properties will.

The one for the highest frequencies, especially the one for wide frequency bands to be used contact rectifier arrangement according to the invention, in which the leads are carried out coaxially, has such a geometric structure and such a shape the coaxial supply line so that this is right up to the between the contact tip and barrier layer resulting in point-like contact a constant wave impedance owns.

Either the inner conductor can end in a contact tip and the outer conductor carries the crystal or, conversely, the outer conductor in a contact tip end and the inner conductor carry the crystal. To further influence the wave resistance is provided according to a further development of the invention that the space between the two conductors near the contact tip with a preferably solid dielectric is filled out. It is also provided that when the rectifier is connected to a voltage source having a low internal resistance between the voltage source and the rectifier a resistor, the size of which is equal to the characteristic impedance of the The rectifier lead is switched on.

The invention is based on the knowledge that two coaxial conical surfaces with a common tip represent a line of constant wave resistance (a special case in which half the opening angle of the outer cone is 90 ° is the combination tip against plate); because the electromagnetic field between two spherical surfaces with a common tip can be written in the spherical coordinates y, 99, & : Here E signifies the electric and H the magnetic field; He, Egg, E, 9, Hr, H ,,, and H3 are the corresponding field components in the Y, 9P or z9 direction; , u is the permeability and E is the dielectric constant. Furthermore, c, the speed of light, co the angular frequency, t the time as a variable, n the circular number and j the unit of the imaginary numbers.

The field strength Hg, (e1) A / cm corresponds to the current density in the bounding conical surfaces. The factor I therefore means the amplitude of the total current I = H-2nysinel. The tension between two edges of the cone, the half opening angles of which are 191 and $ 2, respectively For the wave resistance Z one obtains In particular, in the case of a tip with an opening angle of 2 Ü, the one plane - in which half the opening angle is 90 ° - touches, The diagram according to FIG. 1 shows the dependence of the characteristic impedance Z on the opening angle 2z9 of the tip. For example, for e = 40.5 °, a characteristic impedance of 60 ohms is obtained. For any two angles $ 1 and e2, of which t9 is less than 02, the difference between the abscissa values gives the resistance of the cone pipe. It is Z = Z, - Z2, if Z1 is the wave resistance of the cone with half the opening angle u1 and Z2 is the wave resistance of the cone with half the opening angle e.

The invention is explained in more detail on the basis of eight further figures, FIGS. 2 to 5 show exemplary embodiments according to the invention. The arrangement according to FIG ends at a point. The transition from the tip to the cylindrical coaxial line is carried out in several stages with the interposition of conical lines with the same characteristic impedance. The outer conductor AL carries the crystal. In the cylindrical part it has a diameter D and naturally an angle of inclination of 0 ° with respect to the cylinder axis. The outer conductor initially merges into a cone with an opening angle of 2 -45 'and ends in a plate - the opening angle here is 2 - 90 °. Since the outer conductor carries the crystal in this exemplary embodiment (this will also be the normal embodiment), the inner conductor IL ends in a point. In the present exemplary embodiment, the cylindrical inner conductor has a diameter of 0.37 D, which merges into a cone with an opening angle of 2-17 ° and ends in a tip with an opening angle of 2-40.5 °.

The arrangement according to Fig. 3 shows (also for Z = 60 S2) a reversed polarity rectifier in which the inner conductor carries the crystal, i.e. the inner conductor has the plate carrying the crystal perpendicular to the conductor axis, while the outer conductor ends in a tip . Only the immediate vicinity of the contact tip is drawn up to points a and b. The further course of the conductor profiles up to the coaxial cylindrical line corresponds to FIG. 2 (from a, b on). The half opening angles of the cone of the inner conductor IL are 0, 17, 40.5, 62 and finally 90 °, while the half opening angles of the outer conductor AL are 0, 45, 90, 62 and 40.5 °. It can be seen from these exemplary embodiments that the essence of the invention consists in producing a transition of constant wave resistance between a cylindrical coaxial line and the point-shaped contact point acting as a rectifier with the aid of suitably stepped conical lines.

According to a further development of the invention, the space is between the conductors with a dielectric, for example with Trolitül, the one relative Dielectric constant s = 2.25, can be filled out. This in the space Dielectric introduced between the two conductors can do something at the same time is known from other rectifier arrangements for holding the contact tip contribute. If filled with Trolitul, the arrangements according to Fig. 2 and 3 result in a wave resistance of 40 S2.

Further embodiments shown in FIGS. 4 and 5 show slimmer profiles for the wave resistances Z = 90 SZ in air, i.e. when the dielectric constant is equal to 1 or Z = 60 S2 when filled with Trolitul, i.e. with a dielectric constant of 2.25. In the arrangement according to FIG. 4, the outer conductor AL again carries the crystal, while the inner conductor IL ends in a tip, while in the arrangement according to FIG. 5 the inner conductor carries the crystal and the outer conductor ends in a tip.

The achieved by the rectifier arrangement according to the invention Technical progress is made by calculating the reflection factors that occur shown. As already stated and schematically in the arrangement according to FIG shown, the rectifier is a parallel circuit of a resistor R with a capacitance C. A line is constant at this rectifier contact Characteristic impedance, which is designated by Z, connected. This gives an arrangement which, seen from the outside, has the wave resistance Z, to describe it one can also use the reflection factor o. In the event that Z, = Rist, there is Diagram according to FIG. 7 shows the locus curve of the reflection factor Q (based on Z i), where the relative frequency q = ao CR occurs as a parameter.

As is known, the reflection factor O can be specified by With Z, = R and? 7 = «o CR follows One finds z. B. for q = 0.5 a reflection factor of about o = 0.25.

In the diagram of FIG. 8 there are characteristic voltage curves shown for two operating cases, the voltage curves in the following from the Reflection factor P should be calculated. In the first operational case examined let the voltage at the input of the line Z, be designated by U1 (see Circuit arrangement according to Figure 9, which shows the relationships schematically), this The input voltage is independent of the load from the contact tip, i. H., the internal resistance Ri of the generator, which has an electromotive force Uo, is small compared to the characteristic impedance Z, of the supply line (Ri = 0), like it for example when measuring the voltage on a capacitive voltage divider of the Case is.

In this operating case, the voltage curve U on the crystal depends on the length L of the feed line Z. The input conductance in cross section I is. For the real part one obtains From the current account the voltage curve is obtained If the input voltage U1 is not recorded in cross-section I, but a longer supply line from the characteristic impedance Z, is connected in between, the value of @ is retained for all frequencies, and only the phase angle 9p of the reflection factor Q will increase more rapidly with the frequency. In the limit case of a long supply line, the voltage curve then oscillates in rapid succession between two limit curves, which are given by the limit values cos 99 = ± 1. So there is For these limit curves, i.e. for the greatest possible voltage translation, the amount of the reflection factor is decisive, e.g. B. the ratio is obtained for P = 0.25 These curves are shown in dashed lines in the diagram according to FIG.

Curve I of the diagram according to FIG. 8 shows the course for a certain short lead length, namely L = 0.57 cm was chosen in the present example. The other data on which this exemplary embodiment is based are R = 100 Q, C = 0.3 pF. Since Ri = 0, the voltage Ui at the input of the line Z i is equal to the electromotive force Uo, (Uo = UI) emitted by the generator.

It can be seen that for 27 = 1 a voltage increase occurs. is the supply line Z, longer, the voltage UZ oscillates repeatedly between the dashed lines registered limit curves back and forth, with increasing length more and more often.

The voltage curve in the second of the investigated operating cases is much more favorable if the output of the voltage source, i.e. the generator with the electromotive force Uo, is adapted to the coaxial line, i.e. if the internal resistance of the generator Ri = ZO, because then the line length L is the Curve not affected at all. This operating case is entered in dash-dotted lines in the diagram according to FIG. 8 as curve II.

In the event that the generator is adapted to the line Zo, when the generator has the electromotive force U, the power of the wave entering the cross-section I is while the power of the wave reflected in the cross section I through given is. Thereafter, the power consumed in the terminating resistor R is The voltage curve follows from this The course of the curve II is also independent of the length of the feed line Zo. This favorable case of generator adaptation is z. B. before when the rectifier is used as a voltmeter in a directional coupler. However, even in the first operating case investigated with the low-resistance generator (Ri = 0), the state of adaptation can be established by inserting a small resistor Ri in the supply line, the size of which is equal to the characteristic impedance Z of the supply line (R1 = Z. ), lays.

Claims (5)

PATENT CLAIMS: 1. For highest frequencies, especially for wide frequency bands, contact rectifier arrangement to be used, their leads are designed coaxially, characterized by such a geometric structure and such a shape of the coaxial supply line that it is right up to the point-like contact between the contact tip and the barrier layer has constant wave resistance. 2. Rectifier arrangement according to claim 1, characterized in that the inner conductor terminates in a tip and the outer conductor wearing the crystal. 3. Rectifier arrangement according to claim 1, characterized in that that the outer conductor ends in a tip and the inner conductor carries the crystal. 4. Rectifier arrangement according to one of claims 1 to 3, characterized in that that near the point of contact the space between the two conductors with one preferably solid dielectric is filled. 5. Rectifier arrangement according to One of the preceding claims, characterized in that when connecting the Rectifier to a voltage source having a low internal resistance between the voltage source and the rectifier a resistor, its size is equal to the characteristic impedance of the rectifier lead, switched on is.