KR100309422B1 - Oscillator - Google Patents

Abstract

In the conventional oscillator, since the side of the adjusting conductor is formed in a straight line, even if the length of the slit groove is changed, there is little change in the electrical length from the ground end to the connecting end of the conductor, so that the adjustment range of the oscillation frequency with respect to the length of the slit groove is Narrow.

For this reason, when the adjustment range of the oscillation frequency is to be widened, the area of the conductor portion must be increased, resulting in a problem that the dielectric substrate becomes large.

The oscillator 1 of the present invention has a plurality of dielectric substrates 2 and a resonant conductor 3 formed on the surface of the dielectric substrate 2, the resonant conductors 3 having a main conductor portion 4, And a plurality of dielectric substrates 2 stacked together to connect the resonant conductors 3 in series, so that the main conductor portion 4 and a part of the adjusting conductor portion 5 are connected to each other. The slit groove 6 to be divided was formed, and the length L of the slit groove 6 was changed to adjust the oscillation frequency.

Description

Oscillator {OSCILLATOR}

The present invention relates to an oscillator having a frequency adjustment structure suitable for adjusting the oscillation frequency.

As a resonant conductor for determining the frequency of the oscillation signal oscillated by an oscillator such as a voltage controlled oscillator, a microstripline is provided, and a part thereof is slit to adjust the oscillation signal to a predetermined frequency.

Such a structure of the conventional oscillator 11 and its frequency adjustment method will be described with reference to FIGS.

In the conventional oscillator 11, as shown in FIG. 7, the resonant conductor 13 is formed by the micro strip line on the surface of the dielectric substrate 12. As shown in FIG. The resonant conductor 13 is formed in a substantially T-shape with a main conductor portion 14 extending left and right at the bottom of the figure, and an adjusting conductor portion 15 formed by extending the width of the main conductor portion 14 upwardly in the figure. . The main conductor portion 14 has a ground end 14a at the left end, and a connection end 14b connected to the oscillation circuit, not shown, at the right end, and the adjusting conductor part 15 has side portions 15a and 15a on the left and right sides. The tip portion 15b is formed at the upper end.

Moreover, the slit groove 16 of the longitudinal length M is formed in the substantially center of the main body 14 and the adjustment conductor part 15 from the lower side to the upper side as shown by the dashed-two dotted line. The surface of the dielectric substrate 12 is exposed at the bottom of the slit groove 16.

To adjust the oscillation frequency of the conventional oscillator 11 having such a configuration, the resonant conductor 13 is cut by a cutter or the like to form the slit groove 16 having an appropriate length M. FIG. The impedance of the resonant conductor 13 changes according to the length M of the slit groove 16, and the resonant frequency of the oscillator 11 changes according to the impedance. The relationship between the length M of the slit groove 16 and the oscillation frequency f is shown in FIG.

Since the oscillator 11 has side portions 15a and 15a of the adjusting conductor portion 15 formed in a straight line shape, the ground end 14a of the main conductor portion 14 is changed even if the length M of the slit groove 16 is changed. Change in the electrical length from the end of the slit groove 16 to the connection end 14b through the apex of the slit groove 16 is small, that is, the oscillation frequency change with respect to the length M of the slit groove 16, that is, the slope of the characteristic curve shown in FIG. ((beta)) was small and sufficient frequency adjustment was not possible. Therefore, in order to increase the frequency adjustment range, it is necessary to make the adjustment conductor portion 15 longer to provide a sufficiently long slit groove 16. For this purpose, the dielectric substrate 12 must be enlarged so that the oscillator 11 can be made larger. There was a problem that can not be miniaturized.

1 is a schematic perspective view of an oscillator of the present invention,

2 is a front view of the oscillator of the present invention,

3 is a front view showing a modification of the oscillator of the present invention,

4 is a front view showing another embodiment of the present invention oscillator,

5 is a change curve of the frequency of the oscillator of the present invention,

6 is a schematic perspective view illustrating a frequency adjusting method of an oscillator of the present invention;

7 is a schematic diagram of a conventional oscillator,

8 is a change curve of a frequency of a conventional oscillator.

※ Explanation of symbols for main parts of drawing

1: oscillator 2: dielectric substrate

3: resonant conductor 4: conductor part

4a: ground terminal 4b: connection terminal

5: Adjusting conductor part 5a: Side part

5b: Tip 6: Slit Groove

7: through-hole 8: conductive paste

9: mounting table 10: cutter

10a: Blade tip

The oscillator of the present invention is a first means for solving the above problems, wherein a plurality of dielectric substrates have resonant conductors formed on each surface for determining the frequency of the oscillation signal oscillated by the oscillator, and the resonant conductors are formed in a band-shaped LED. A body portion and an adjusting conductor portion formed by extending the width of the main body portion from a portion of the main body portion, wherein the plurality of dielectric substrates are stacked on each other to form one laminated substrate, and an oscillation circuit is mounted on the laminated substrate, The resonant conductors of the dielectric substrate are electrically connected in series with each other by through hole conductors passing through the dielectric substrate.

The oscillator of the present invention is a second means for solving the above problems, wherein one dielectric substrate has resonant conductors formed on both surfaces thereof to determine the frequency of the oscillation signal oscillated by the oscillator, and each resonant conductor has a band shape. A main conductor portion and an adjusting conductor portion formed by extending the width of the main conductor portion from a portion of the main conductor portion, and an oscillation circuit is mounted on the dielectric substrate, and the resonant conductors on both sides are formed by through-hole conductors penetrating through the dielectric substrate. Electrically connected in series with each other.

In the oscillator according to the present invention as described above, the frequency of the oscillation signal is determined according to the length of the slit groove provided by applying one or more resonant conductors from the main conductor part to the adjusting conductor part and slit together with the dielectric substrate.

(Example)

An oscillator of the present invention and a frequency adjusting method thereof will be described with reference to FIGS. 1 to 6.

The oscillator of the present invention is provided with a microstrip line as a resonant conductor for determining the frequency of an oscillation signal oscillated by an oscillator. The oscillator slits a portion thereof to adjust the oscillation signal to a predetermined frequency.

In the oscillator 1 of the embodiment of the present invention, as shown in Figs. 1 and 2, a plurality of dielectric substrates 2 made of a resin material or the like, for example, are stacked.

On the surface of the plurality of dielectric substrates 2, a resonant conductor 3 composed of micro strip lines is formed. The resonant conductor 3 has a strip-shaped main body 4 formed in contact with one end of the dielectric substrate 2 shown in FIG. 1 and the side portions 5a and 5a extending in a direction perpendicular to the main body 4. And the adjusting conductor portion 5 having the tip portion 5b, the outer shape is formed in a substantially T-shape.

Among the resonant conductors 3 and 3 formed on the two dielectric substrates 2 and 2, as shown in FIG. ) Sandwiched into a sandwich.

Moreover, the longitudinal slit groove 6 which divides a part of the main conductor part 4 and the adjustment conductor part 5 to the left and right in the substantially center part of the said main conductor part 4 and the adjustment conductor part 5 is formed.

The slit groove 6 is formed by cutting the dielectric substrate 2 of the slit groove 6 together with the micro stripline by changing the oscillation frequency adjustment method described later to change the length L of the slit groove 6. It is possible to adjust by changing the oscillation frequency.

As shown in Figs. 1 and 2, the oscillator 1 of the present invention in which two dielectric substrates 2 are stacked has a ground terminal 4a on the right side of the main body portion 4 of the lower dielectric substrate 2. The ground end 4b is formed in the right side of the main body part 4 formed in the dielectric substrate 2 above.

In addition, a through hole 7 penetrating the dielectric substrates 2 and 2 is formed near the left side of each of the main body portions 4 and 4. Copper plating or the like is formed on the inner surface of the through hole 7 so that the inner surface of the through hole 7 and the resonant conductor 3 are conductive.

The conductive paste 8 flows into the through-holes 7 of the two dielectric substrates 2 and 2 stacked up, and the conductive pastes 8 are connected in series by the upper and lower conductors 3 and 3. have.

The oscillation frequency adjustment method of the present invention oscillator 1 having such a configuration will be described with reference to FIG. Here, a description will be given of a laminated substrate in which two dielectric substrates 2 and 2 are laminated.

First, an oscillator 1 in which the resonant conductors 3 and 3 of the two dielectric substrates 2 and 2 are conducted by the conductive paste 8 is mounted on a small table (not shown). Install in (9). This mounting table 9 is movable in the directions of arrows A, B, C, and D. FIG.

The cutter 10 is provided with a cutter 10 having a cutting edge 10a of a desired diameter made of an end mill or the like. Then, the cutter 10 is rotated at a high speed to move downward in the direction of the arrow E. FIG.

Then, the cutting edge 10a of the cover 10 cuts through a portion of one end portion of the two dielectric substrates 2 and 2. Then, while the cutter 10 is lowered, the mounting table 9 is moved in the direction of the arrow C to divide the main body portion 4 and the part of the adjusting conductor portion 5 of the dielectric substrate 2 so that the slit groove 6 is formed. Form. That is, the slit groove 6 is formed simultaneously with the process of cutting a part of the dielectric substrate 2.

At this time, observe the frequency monitoring device (not shown), such as an oscilloscope, and move the mounting table 9 in the direction of arrow C, and the length of the slit groove 6 until the oscillation frequency of the oscillator 1 becomes a desired value (L). ) To adjust.

Thus, the groove | channel 6 is formed by the cutter 10, and the length L of this slit groove 6 is changed, and the connection end 4b from the ground end 4a of the main body part 4 to the oscillation circuit is changed. The electrical length up to can be made long.

Then, the resonant conductors 3 connected in series of the stacked plurality of dielectric substrates 2 are partially cut in the slit grooves 6 to thereby connect the connecting ends from the ground end 4a of the main conductor portion 4 to the oscillation circuit. The electrical length up to (4b) can be made multiple times longer than before.

Therefore, as shown in FIG. 5, the curve angle (alpha) of the oscillation frequency f with respect to the length L of the slit groove 6 can be made larger than the angle (beta) of the conventional curve.

In addition, the depth of the slit groove 6 or the moving speed of the mounting table 9 can be controlled by a control unit (not shown) such as a computer. When the adjustment groove 6 reaches the desired frequency f, it is automatically It is also possible to separate the cutter 10 from the dielectric substrate 2 on which the oscillator 1 is formed since the movement of the mounting table 9 is stopped.

In addition, the resonator conductor 3 of the oscillator 1 of the present invention is formed on the surfaces of the plurality of dielectric substrates 2 to sandwich the resonant conductors 3 of the lower dielectric substrate 2 to the upper dielectric substrate 2. As illustrated in FIG. 3, as shown in FIG. 3, an oscillator 1 composed of two dielectric substrates 2 has a dielectric substrate 2, in which no resonant conductor 3 is formed. The back surfaces of 2) may be connected in opposing states, and the resonant conductors 3 may be formed to face outwards, respectively, and the resonant conductors 3 and 3 may be connected in series.

As another embodiment of the present invention, one dielectric substrate 2 shown in Fig. 4 and two resonant conductors 3 and 3 formed on the front and back surfaces of the dielectric substrate 2 are provided. 3 and 3 consist of a strip-shaped main conductor part 4 and an adjusting conductor part 5 extending perpendicularly from the main conductor part 4 to connect two resonant conductors 3 and 3 in series. You can do it.

The oscillation frequency adjusting method of the oscillator 1 of the present invention comprising one or a plurality of dielectric substrates 2 as described above includes a main body portion 4 and an adjustment diagram of one or more dielectric substrates 2. A slit groove 6 for dividing a part of the body part 5 is formed at the same time as the step of cutting a part of the dielectric substrate 2 to adjust the oscillation frequency.

The oscillator of the present invention includes a plurality of dielectric substrates and a resonant conductor formed on the surface of the dielectric substrate, the resonant conductors comprising a strip-shaped main conductor portion and an adjusting conductor portion extending perpendicularly from the main conductor portion. Since the plurality of dielectric substrates are stacked to connect the resonant conductors in series, the slit grooves formed in the laminated dielectric substrates can increase the variation of the oscillation frequency with respect to the length of the slit grooves. Since the length of the slit groove can be made shorter than before, a small oscillator can be provided.

In addition, since the oscillator can be made compact, the material cost can be reduced, and low-cost oscillation frequency can be provided.

In addition, the oscillator of the present invention includes one dielectric substrate and two resonant conductors formed on the front and rear surfaces of the dielectric substrate, the resonant conductors extending in a direction perpendicular to the strip-shaped main conductor portion and the main conductor portion. It consists of an adjustable conductor section, and since the two resonant conductors are connected in series, the same effect as stacking two dielectric substrates with one dielectric substrate can reduce the number of parts and lower cost oscillator. Can be provided.

In addition, the oscillation frequency adjusting method of the oscillator of the present invention comprises a step of cutting a part of the dielectric substrate into a slit groove for dividing the main conductor portion and a part of the adjusting conductor portion of one or more of the dielectric substrates. Since the oscillation frequency is adjusted by adjusting the length of the slit groove with a cutter or the like, a large oscillation frequency change can be obtained, and an efficient oscillation frequency can be adjusted.

Claims (2)

In the plurality of dielectric substrates, resonant conductors for determining the frequency of the oscillation signal oscillated by the oscillator are formed on each surface thereof. The resonant conductor includes a strip-shaped main conductor portion; A part of the main body part comprising an adjusting conductor part formed by widening the main body part, The plurality of dielectric substrates are stacked on each other to form one laminated substrate, and an oscillation circuit is mounted on the laminated substrate, and the resonant conductors of each dielectric substrate are electrically connected in series by a through hole conductor passing through the dielectric substrate. Connected, And the frequency of the oscillation signal oscillating to the oscillator is determined according to the length of the slit groove provided by slitting the at least one resonant conductor together with the dielectric substrate from the main conductor portion to the adjusting conductor portion. One dielectric substrate has resonant conductors formed on both sides thereof to determine the frequency of the oscillation signal oscillated by the oscillator. Each resonant conductor includes a strip-shaped main conductor portion; A portion of the main body portion is formed of an adjustment conductor portion formed by widening the main body portion, An oscillation circuit is mounted on the laminated substrate, and the resonant conductors on both sides are electrically connected in series with each other by a through hole conductor passing through the dielectric substrate. And the frequency of the oscillation signal oscillating to the oscillator is determined according to the length of the slit groove installed by slitting the at least one resonant conductor together with the dielectric substrate from the main conductor portion to the adjusting conductor portion.