JPH09260988A - Tuning circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an attenuation pole in the characteristic without increasing number of components and to sufficiently attenuate an undesired signal. SOLUTION: The circuit is provided with an input coil L1, an output coil L2 and a tuning coil L3 with which a capacitive element C1 or a varactor element is connected in parallel. Then each coil is wound on a drum core 11 having two winding slots and three guards. In this case, the tuning coil L3 is wound onto the two slots separately but the input coil L1 and the output coil L2 are wound on one winding slot and a relation of K1 .K2 /K3 <1 is provided (where K1 is a coupling coefficient between the tuning coil and the input coil, K2 is a coupling coefficient between the tuning coil and the output coil, and K3 is a coupling coefficient between the input coil and the output coil). Then an attenuation pole is provided at a frequency higher than the tuning frequency.

Description

Detailed Description of the Invention

[0001]

The present invention relates to a tuning circuit,
In particular, it relates to a tuning circuit used in a radio receiver.

[0002]

2. Description of the Related Art FIG. 7 is a circuit diagram of a conventional tuning circuit, and FIG. 8 is a sectional view showing a state in which each coil of FIG. 7 is wound around a drum core. The conventional tuning circuit has an input coil L
9, an output coil L10, a tuning coil L11, and a capacitor C4. A capacitor C4 is connected in parallel to the tuning coil L11. Tuning coil L11 and capacitor C4
The connection point 70 is grounded. And the input coil L
The output coil L10, the output coil L10, and the tuning coil L11 are wound around one winding groove of a drum core 81 having two flanges as shown in FIG. The drum core 81 is covered with a pot-shaped core 84 screwed into the case so as to be vertically movable.

[0003]

Such a tuning circuit is
The tuning frequency of the tuning coil L11 and the capacitor C4 is made to match the frequency of the desired input signal. However, such a tuning circuit has a problem that when an unnecessary signal is present near the tuning frequency, the unnecessary signal cannot be sufficiently attenuated. To solve this problem, the tuning coil L11
There is one in which another inductance element is connected between the connection point 70 between the capacitor C4 and the capacitor C4 and the ground, and an attenuation pole is provided at the frequency of an unnecessary signal. However, there has been a problem that the circuit configuration becomes complicated, the number of parts increases, and the tuning circuit becomes expensive.

An object of the present invention is to provide a tuning circuit in which an attenuation pole can be provided at a desired frequency without increasing the number of parts and an unnecessary signal can be sufficiently attenuated.

[0005]

A tuning circuit according to the present invention comprises an input coil, an output coil, and a tuning coil in which a capacitive element or a variable capacitive element is connected in parallel, and has a three-plate collar having two winding grooves. Using a drum core, the tuning coil is divided into two grooves and wound, the input coil and the output coil are wound in one winding groove, and the relationship of K1 ・ K2 / K3 <1 is established. Provide an attenuation pole at high frequency.
(However, K1 is the coupling coefficient between the tuning coil and the input coil, K
2 is a coupling coefficient between the tuning coil and the output coil, and K3 is a coupling coefficient between the input coil and the output coil. )

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION The tuning circuit of the present invention comprises an input coil, an output coil, and a tuning coil in which a capacitive element is connected in parallel. The input coil, the output coil and the tuning coil are wound around a drum core having three flanges having two winding grooves. At this time, the tuning coil is divided into two winding grooves and wound, and the input coil and the output coil are wound in one winding groove. The coupling relationship among the input coil, the output coil, and the tuning coil is K1 · K2 / K3 <1. (However,
K1 is a coupling coefficient between the tuning coil and the input coil, K2 is a coupling coefficient between the tuning coil and the output coil, and K3 is a coupling coefficient between the input coil and the output coil. )

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of a tuning circuit of the present invention will be described below with reference to FIGS. FIG. 1 is a circuit diagram showing a first embodiment of a tuning circuit of the present invention, and FIG. 2 is a sectional view showing a state in which each coil of FIG. 1 is wound. 1 and 2, 11 is a drum core, L1 is an input coil, L2 is an output coil, and L3 is a tuning coil. The input coil L1 is connected between the input terminals 12 and 13. The output coil L2 is connected between the output terminals 14 and 15. A capacitor C1 is connected in parallel to the tuning coil L3. Connection point 10 between tuning coil L3 and capacitor C1
Is grounded. This input coil L1 and output coil L
2. The tuning coil L3 is wound around the drum core 11 of three flanges having the two winding grooves 16 and 17, and is magnetically coupled. The tuning coil L3 is divided into two winding grooves 16 and 17 and wound to form L3A and L3B. The input coil L1 and the output coil L2 are wound around the upper winding groove 16. The drum core 11 having three flanges is covered with a pot-shaped core 18 screwed in a case so as to be vertically movable.

In such a tuning circuit, the tuning frequency of the tuning coil L3 and the capacitor C1 is matched with the frequency of a predetermined signal input from the input coil.

FIG. 3 is an equivalent circuit diagram showing a case where a signal source is connected to the input coil L1 of this tuning circuit and a load is connected to the output coil L2. In FIG. 3, R1 is a signal source resistance, R2 is a load resistance, M1 is an inductive inductance between the input coil L1 and the tuning coil L3, M2 is an inductive inductance between the output coil L2 and the tuning coil L3, and M is
Reference numeral 3 is an induction inductance between the input coil L1 and the output coil L2. The same parts as those in FIG. 1 are designated by the same reference numerals. It is assumed that the voltage E _i is applied to the input coil L1 via the signal source resistor R1 and E ₀ is obtained between the ends of the load resistor R2 from the output coil L2. Then, if the closed currents flowing through the coils are i1, i2, and i3, the closed-circuit matrix of the equation (1) is obtained.

(Equation 1) Here, when the coupling coefficient between the input coil L1 and the tuning coil L3 is K1, the relationship with M1 is expressed by equation (2). M1 = K1 (L1 · L3) ^1/2 (2) When the coupling coefficient between the tuning coil L3 and the output coil L2 is K2, the relationship with M2 is expressed by equation (3). M2 = K2 (L3 · L2) ^1/2 (3) Further, assuming that the coupling coefficient between the input coil L1 and the output coil L2 is K3, the relationship with M3 is expressed by equation (4). M3 = K3 (L1 · L2) ^1/2 (4) Then, by inputting each constant of this tuning circuit to the equation (1), the equation (2), the equation (3) and the equation (4), It is possible to obtain the relationship between the coupling coefficient between the coils and the relative position of the tuning frequency and the frequency of the attenuation pole. In FIG. 4, the horizontal axis represents the ratio between K2 and K3, and the vertical axis represents the ratio between the tuning frequency F ₀ and the attenuation pole frequency F ₁ . In such a tuning circuit, the existence of the attenuation pole at a frequency higher than the tuning frequency means that F ₁ / F ₀ has a finite value larger than 1. Therefore, it can be seen from FIG. 4 that the condition for providing the attenuation pole is K1 · K2 / K3 <1 (5). Further, the attenuation pole is provided at a position apart from the tuning frequency by reducing K1.
Further, the attenuation pole is provided at a position away from the tuning frequency by increasing K2 / K3. That is, the attenuation pole can be provided at a desired frequency by changing the values of K1, K2, and K3 within the range of Expression (5).

Considering such a relationship in the tuning circuit having the winding structure shown in FIGS. 1 and 2, since the tuning coil L3 is divided into the winding grooves 16 and 17 in the above K1 and K2, the equation ( It is represented by 6). K1 = K2 = Ka (L3B / L3) ^1/2 + Kb (L3A / L3) ^1/2 (6) where Ka is the coupling coefficient between the winding grooves 16 and 17, and the structure of the drum core 11, that is, the winding groove 16 It is a constant that is determined by the thickness of the collar between 17 and 17. Kb is a coupling coefficient in the same winding groove, and usually has a value of about 1. Further, the equation (7) is established between the tuning coil L3 and the divided L3A and L3B. L3 = L3A + L3B + 2Ka (L3A · L3B) ^1/2 (7) Since L1 and L2 of K3 are wound in the same winding groove, formula (8) is established. K3 = Kb≈1 (8) From the formulas (6) and (7), the tuning coil L3 is provided with an inductance required for a predetermined tuning frequency under constants Ka and Kb determined by the structure of the drum core 11. However, it is understood that arbitrary coupling coefficients K1 and K2 can be realized by changing the division ratio of L3A and L3B. Therefore, according to FIG. 4, K1 for providing an attenuation pole at a desired position,
An attenuation pole can be provided at a desired position on the high frequency side of the tuning frequency by determining K2 and K3 and determining the division ratio of L3A and L3B by the equations (6), (7) and (8).

FIG. 5 is a circuit diagram showing a second embodiment of the tuning circuit of the present invention. In FIG. 5, 51 is a drum core of three flanges, L4 is an output coil, L5 is a tuning coil, and C2.
Is a capacitor. The tuning coil L5 is a capacitor C
2 are connected in parallel, and divided into two winding grooves of the drum core 51 and wound to form L5A and L5B. The tuning coil L5A wound on the upper side is tap 5
2 are formed. An input coil is formed by connecting the tap 52 to the input terminal 53. The output coil L4 is wound around the groove on the upper side of the drum core 51 and is connected between the output terminals 54 and 55.

FIG. 6 is a circuit diagram showing a third embodiment of the tuning circuit of the present invention. In FIG. 6, 61 is a drum core of three flanges, L6 is an input coil, L7 is an output coil, and L8.
Is a tuning coil. A variable capacitance diode C3 is connected in parallel to the tuning coil L8. And the tuning coil L
In No. 8, L8B is wound around the upper winding groove of the drum core 61, and L8A is wound around the lower winding groove. Input coil L6
Is connected between the input terminals 62 and 63, and is wound around the winding groove on the lower side of the drum core. The output coil L7 is connected between the output terminals 64 and 65 and wound around the winding groove on the lower side of the drum core. The tuning circuit thus formed is used, for example, in a high frequency tuning circuit of an AM receiver. At this time, an antenna such as a loop antenna 66 is connected to the input terminals 62 and 63.

Although the embodiment of the tuning circuit of the present invention has been described above, the present invention is not limited to this embodiment. For example, the input coil and the output coil may be drawn out by taps formed on the tuning coil. Further, in the first and second embodiments, the input coil and the output coil may be wound around the groove on the lower side of the drum core. further,
In the third embodiment, the input coil and the output coil may be wound around the groove on the upper side of the drum core.

[0014]

The tuning circuit of the present invention has three winding grooves.
Using a single-tsuba drum core, the tuning coil was divided into two grooves and wound, and the input coil and the output coil were wound in one of the grooves so that the relationship of K1 · K2 / K3 <1 was established. Therefore, the attenuation pole can be provided without increasing the number of parts, and unnecessary signals can be attenuated by 20 dB or more as compared with the conventional one. Further, the tuning circuit of the present invention includes a tuning coil 2
Since the frequency of the attenuation pole can be freely changed by the ratio of dividing into one groove, it is possible to follow the frequency of the image signal by connecting a variable capacitance element in parallel with the tuning coil to form a high frequency tuning circuit of the radio receiver. it can.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a first embodiment of a tuning circuit of the present invention.

FIG. 2 is a cross-sectional view showing a state in which each coil of FIG. 1 is wound.

FIG. 3 is a circuit diagram equivalently showing a case where a signal source and a load are connected to the tuning circuit of the present invention.

FIG. 4 is a graph showing the relationship between the coupling coefficient between the coils and the relative position of the tuning frequency and the frequency of the attenuation pole.

FIG. 5 is a circuit diagram showing a second embodiment of the tuning circuit of the present invention.

FIG. 6 is a circuit diagram showing a third embodiment of the tuning circuit of the present invention.

FIG. 7 is a circuit diagram of a conventional tuning circuit.

FIG. 8 is a cross-sectional view showing a state in which each coil of FIG. 7 is wound around a drum core.

[Explanation of symbols]

 11 Drum core L1 input coil L2 output coil L3 tuning coil

Claims (6)

[Claims] 1. An input coil, an output coil, and a tuning coil in which a capacitive element is connected in parallel are used, and a drum core of three flanges having two winding grooves is used, and the tuning coil is divided into two grooves. The tuning circuit is characterized in that the input coil and the output coil are wound around one winding groove to have a relation expressed by the following equation, and an attenuation pole is provided at a frequency higher than the tuning frequency. K1 · K2 / K3 <1 where K1 is the coupling coefficient between the tuning coil and the input coil, K2
Is a coupling coefficient between the tuning coil and the output coil, and K3 is a coupling coefficient between the input coil and the output coil. 2. An input coil, an output coil, and a tuning coil in which a variable capacitance element is connected in parallel are used, and a drum core of three flanges having two winding grooves is used, and the tuning coil is divided into two grooves. The tuning circuit is characterized in that the input coil and the output coil are wound around one winding groove so as to have a relationship represented by the following formula, and an attenuation pole is provided at a frequency higher than the tuning frequency. K1 · K2 / K3 <1 where K1 is the coupling coefficient between the tuning coil and the input coil, K2
Is a coupling coefficient between the tuning coil and the output coil, and K3 is a coupling coefficient between the input coil and the output coil. 3. The tuning circuit according to claim 1, wherein the input coil is configured by being drawn out by a tap formed on the tuning coil. 4. The output coil is configured by being drawn out by a tap formed on a tuning coil.
The tuning circuit according to any one of 2 and 3. 5. The tuning circuit according to claim 2, wherein a loop antenna is connected to the input coil. 6. The tuning circuit according to claim 2, wherein the tuning circuit constitutes a high frequency tuning circuit of a radio receiver, and the attenuation pole suppresses an image signal.