FI90167C - Tuning of a voltage controlled oscillator - Google Patents

Description

The invention relates to a voltage-controlled oscillator in which the oscillation is generated in a resonator circuit comprising a stripline. A voltage-controlled oscillator - Avstämning av en spänningsstyrd oscillator 1 90167

Voltage controlled oscillators (VCOs) are oscillation circuits 10 whose output frequency can be changed by the control DC voltage. A typical application of such oscillators is a phase locked loop (PLL) where it is used to synchronize two signals in both phase and frequency. The second signal may be, for example, the local oscillator signal of the radio device 15, the other being the received frequency. In such applications, the control voltage is a correction voltage proportional to the phase difference between the loop output frequency and the reference frequency, which adjusts the output frequency of VC0 so that it follows the reference frequency.

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In oscillators, vibration can be induced in a number of different ways. An active element, a bipolar transistor or an FET having a resonant circuit in the feedback branch is usually used, or a resonant circuit before the transistor is used, as is customary in VCO applications, from which the oscillation frequency is applied to the base of the transistor acting as an oscillation amplifier and further amplified. The oscillation circuit itself, in turn, consists of the LC-30 series resonance circuit formed by capacitances and inductances. The inductance of the oscillation circuit can be implemented, for example, with a waveguide, a hollow resonator or using a stripline. The stripline is a good and used solution due to the reproducibility of the fabrication, the relatively cheapness and the small size required at higher frequencies, and this invention relates to a resonant circuit implemented with a stripline. The capacitance of the oscillation circuit includes a capacitor, at least one capacitance diode and an input capacitance of the transistor. The characteristic frequency of the oscillation circuit 2 9 Π167 can be changed by changing the capacitance of the capacitance diode (varactor) with an external control DC voltage. A VCO circuit using a stripline resonator as described above is disclosed in DE-3 690 396 by a picture-5 oscillator circuit.

Such connections are characterized in that the other end of the stripline belonging to the series resonant circuit is grounded. The oscillator is designed for the desired frequency, when the varactor-10 is used for the desired center frequency, by dimensioning the capacitors and the impedance of the stripline, i.e. its length and width to meet the required properties. Once the computational dimensioning is done, the VCO circuit can be assembled. It is then tested whether it also meets the required specifications for frequency. Since the capacitance values of the capacitors of the resonant circuit always have a certain tolerance, it means in practice that the finished voltage-controlled oscillator often still has to be tuned to reach the desired frequency. The commonly used method is to change the active length of the resonator strip. It is known to change said length by milling a piece off the resonator strip in the longitudinal or width direction of the strip. Another known way is to make a row of holes in the strip in the longitudinal direction close to its grounded end at the manufacturing stage. Each hole extends through the circuit board to the opposite side of its resonator strip with a ground plane foil or strip. The walls of each hole are metallized or tinned, with the resonator strip on one side of the insulating plate being in metallic contact with the ground plane on the opposite side of the insulating plate at each hole. In the finished circuit, the tuning can now be performed by drilling out the bushing or tinning out of the grounding hole, whereby the grounding is interrupted at this point and the active length of the strip changes. 35

The methods described above for shortening the active length of a resonator strip have some disadvantages. However, changing the length or width of the strip by milling makes it possible

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3 90167 sex precise tuning, but the method is technically cumbersome because the measurement and milling have to be done alternately. First, very little strip is milled, then the frequency is measured, again milled and measured, etc., until the exact 5 frequency is reached. Drilling through the grounding holes is slightly faster than the tuning, but the disadvantage is the resulting drilling debris, which easily remains inside the device, e.g. a telephone. The length and spacing of the grounding holes in the longitudinal direction of the strip determine the accuracy of the tuning.

The present invention provides a way to change the active length of a resonator strip which does not have the disadvantages of known methods. Tuning is fast and no harmful metal pain-15 Rua is generated. The invention is characterized by what is stated in claim 1.

The invention is therefore based on holes drilled in the strip and extending through the circuit board. Holes are drilled in two or more rows in the longitudinal direction of the resonator strip and in such a way that the holes of the adjacent rows are overlapped with respect to each other, i.e. in the transverse direction of the resonator, the rows of holes form an oblique pattern. In contrast to the prior art, these via holes are electrically non-conductive and during tuning the grounding is performed by riveting the conductive rivet to the lead hole, making the rivet ends in tight contact with both the resonator strip and the metal ground strip on the opposite side of the insulator plate.

In another embodiment of the invention, the ground plane metal foil strip is on the same side of the insulating plate as the resonator strip, with holes passing through the plate being drilled in both the strip 35 and the ground plane strip. A branch rivet with a branch spacing corresponding to the distance between the rows of holes is set to connect the resonator strip to the ground plane. The end of the strip and the edge of the grounding strip are shaped and the holes are suitably drilled 4 90167 so that only one standard plate branch rivet can be used.

The invention will be described more illustratively with reference to the accompanying Figures 5, in which Figure 1 shows the change in active length of a resonator strip by grounding it on a foil strip on the opposite side of the insulating plate, Figure 2 shows a cross-section of the case of Figure 1 4 shows a schematic cross-section of the grounding of Fig. 3, and 15 Fig. 5 shows another embodiment of the grounding of the type of Fig. 3.

The series resonance coupling according to the figures is mainly of the principle-coupling nature. It comprises a capacitor 2, which represents all the capacitors belonging to the resonant circuit, and a stripline 1 located on an insulating plate 3, e.g. a circuit board, and the end of the capacitor away from the capacitor is grounded by a ground conductor M to a ground plane 25 on the insulating plate 3. the form is not limited in any way. Voltage control is applied to terminal a and a resonant frequency output signal is obtained from terminal b. The resonant frequency and thus the output frequency of the VCOs is tuned by changing the active length of the resonator strip 1. This is done according to Figures 1 and 2 by drilling a plurality of holes H in the grounded end of the strip 1. The holes pass through the strip wire 1, the insulating plate 3 and the ground strip 5. The holes H are drilled in at least two longitudinal rows of the strip 1 with respect to pi-35 in the wind direction. According to Figure 1, the overlap is L, which is thus also the smallest possible earthing adjustment interval. In practice, the smallest possible overlap L is determined by the smallest possible drilling distance B, which in turn depends on the hole

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5 90167 of the diameter and the amount of material necessary between the holes to maintain mechanical strength. According to Figure 2, the resonant frequency is tuned by connecting the circuit containing the VCO to the tester and measuring the VCO frequency. If it deviates from the desired one, the active length of the strip 1 is changed by placing a rivet leading to a hole in the ground conductor M at a suitable distance, e.g. copper rivet 4. The hole can be selected so that a separate ground conductor is used to test the desired frequency. Riveting can be done with a plastic or ceramic tool made of insulating material, in which case the measurement and tuning can be done simultaneously. The riveting provides a reliable electrical contact between the rivet 4 itself and the strip 1 15 and the grounding strip 5. In this way, by grounding the resonator strip 1 from the point indicated by the measurement, its active length can be shortened and tuning to the desired value can be performed easily and quickly.

Figures 3 and 4 show an alternative embodiment of the invention. In this case, the foil strip 5 acting as a ground plane is on the same side of the insulating plate 3 as the strip resonator 1. As shown in Fig. 3, the strip 5 is a strip parallel to the strip line 1. The grounded end of the stripline resonator 1 is beveled as shown in Fig. 3, and holes H passing through the strip 1 and the insulating plate 3 are drilled near this beveled end. The resonator-side end of the ground plane strip 5 is beveled accordingly and the ends of the strip 1 Holes similar to those of the ends of the strip 1 are drilled in the ends of the strip 5. A branch rivet 4 is now used for tuning, which electrically connects the stripline 1 and the ground strip 5 by inserting one branch thereof into the hole of the stripline and the other branch into the corresponding hole 35 of the ground plane strip 5. Since the rows of holes are parallel, a similar branch rivet can be used all the time. The ends of the branch rivet 4 extending to the opposite side of the circuit board 3 are bent as shown in Fig. 6 9 Π1 6 7 4. A suitable insulating tool can be used for this.

Fig. 5 shows another variation of the case where the ground plane strip 5 is on the same side of the insulating plate 3 as the strip resonator 1. In this case only one hole is drilled in the strip 5 and a row of holes is drilled in the strip line, each hole spaced from the foil strip 5 that is, they are located on the circumference of 10 circles with the center of the circle being a hole in the foil strip 5. In this way, branch rivets 4 of the same width can be used again for tuning. Tuning is done simply by measuring which of the holes in the stripline 1 gives the best result when it is grounded. This hole is then connected with a branch rivet 4 to the hole 5 of the ground plane strip. The ends of the rivet 4 extending to the opposite side of the circuit board are bent as shown in Fig. 4.

With the method shown, the active length of the resonator strip 20 can be easily and quickly changed by changing its ground point. Tuning can be performed simultaneously with VC0 frequency measurement. The method can be used regardless of whether the ground plane foil strip is on the same side or on a different side of the insulating sheet than the re-25 sonator strip. The invention is not limited to the embodiments described above, but there are numerous implementation options. The hole pattern to be drilled in the resonator strip may be different from the above, it is only essential that the resonator strip at hole 30 with a rivet gives a different VCO frequency for each hole and that the distance between the holes in the longitudinal direction of the resonator strip is small enough to achieve sufficiently low step tuning.

Claims (7)

A method of tuning the frequency of an oscillator, wherein the oscillator comprises an oscillation circuit formed by a capacitive means (2) and a resonator band (1) arranged on the surface of an isolation plate (3), wherein a change in the active length of the resonator band causes a change in the oscillation frequency, characterized in that - at the end of the resonator band (1) to be grounded, a number of shells (H) passing through the insulating plate (3) are drilled and located at a distance (L) from each other in the resonator path - its (1) longitudinal direction, - measure at which heel of the resonator band (1) the grounding to the grounding band (5) on the surface of the insulating plate (3) gives the closest desired frequency for the oscillator, 15. In the core a current conducting rivet (4) is placed, one of which even at riveting, an electrical contact forms to the resonant band (1) and the other end forms an electrical contact to the grounding band (5), the resonator band (1) being grounded at said shark. 20 Method according to claim 1, characterized in that the grounding band (5) is placed on the opposite surface of the insulation plate (3) with respect to the resonator band (1) so that the drilling heels (H) pass through this as well, whereby a pin-shaped rivet (4) used for grounding. Method according to claim 1, characterized in that the grounding band (5) is placed on the same side of the insulating plate (3) as the resonator band (1), that at least one heel boring through the insulating plate (3) and the rivet (4) is drilled. is a cross-arm rivet, one arm of which is placed in a heel that likes through the resonator band (1) and the other arm in a heel that likes through the grounding band (5). 35 Method according to claim 2, characterized in that the heel is drilled in two or more rows in the longitudinal direction of the resonator band (1) so that the heel forms oblique rows in the transverse direction of the resonator band. 10 901 f-; 5. A method according to claim 1, characterized in that the heels are drilled so as to form at least one oblique row in the transverse direction of the resonator band (1) and in the grounding band (5) the heels are drilled so as to form at least one row parallel to the the line formed in the resonator band and each shark in the resonator band corresponds to a heel of the grounding band at the same distance in the longitudinal direction of the resonator band. 6. A method according to claim 3, characterized in that the heel drilled in the resonator band is perpendicular to a circle whose center point is formed by the heel to be drilled in the grounding band. Use of the method according to any of the preceding claims for tuning the frequency of a voltage controlled oscillator (VCO). Il