JPH0129322B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention is applicable to television stations, CATV
The present invention relates to a bandpass filter for a high frequency tuned amplifier used in a converter, etc., and particularly to a bandpass filter having a trap that can be set at an arbitrary position with respect to the passband frequency.

A conventional bandpass filter section of a tuned amplifier generally used for high frequencies is shown in FIG.

In Figure 1, 1 is an input terminal, 2 is an amplification element (transistor in this example), 3 is a primary tuning circuit, and 4
is a coil, 5 is a capacitor, 6 and 7 are two coil parts obtained by dividing the coil 4, 8 is a secondary tuning circuit, 9 is a coil, 10 is a capacitor, 11 and 12 are two coil parts obtained by dividing the coil 9, 1
3 indicates an output terminal.

The coils 4 and 9 are inductively coupled, and the two tuned circuits 3 and 8 form a double tuned circuit. The output electrode 14 of the amplifying element 2 is coupled to the connection point between the coil parts 6 and 7 and is also connected to the output terminal 13
is coupled to the connection point between coil portions 11 and 12.

The double-tuned circuits 3 and 8 of the high-frequency tuned amplifier constructed in this manner have characteristics as shown in FIG.

In FIG. 2, 16 indicates a transmission band from frequencies ₁ to ₂ , and 15 indicates a trap occurring at a frequency higher than the transmission band. This trap 15 is constructed by connecting one of the divided coils (7 or 12) and a capacitor (5 or 10) in series, as can be understood from the equivalent circuit in Figure 3, which is a rewrite of the circuit in Figure 1. This is caused by resonance.

Therefore, as shown in FIG. 1, in a tuned circuit using step-up coils, this trap frequency 15 is
1 does not contribute, it always occurs above the transmission band 16. In a tuned circuit using a step-up using a capacitor, the opposite is true, and the trap occurs at the lower side (not shown).

By the way, in high-frequency tuned amplification such as television tuners and CATV converters, there are cases where it is desired to greatly attenuate the signal at a predetermined frequency higher than the transmission band 16 for various reasons. In some cases, the trap created by one of the divided coils and the capacitor may be actively utilized.

However, the trap frequency that occurs in a tuned circuit using a capacitor step-up or a coil step-up as shown in FIG. 1 cannot be selected to an arbitrary value. This is because when the transmission band 16 is given, the Q and degree of coupling of the tuning circuit are uniquely determined, and the step-up ratio is also determined. Therefore, in order to realize a trap for a predetermined frequency as described above, it was necessary to add another trap circuit (not shown). However, in this case, between the added trap circuits or the series resonant circuit (coil 7 and capacitor 5, or coil 12 and capacitor 10) formed by the added trap circuit and the tuned circuit, Mutual influences occur, making it difficult to adjust the trap frequency and affecting the characteristics of the transmission band, among other drawbacks.

The present invention eliminates the above-mentioned drawbacks in conventional circuits, and its first purpose is to provide a configuration in which a trap can be provided at a predetermined position without impairing the characteristics of the transmission frequency band. In particular, a second object is to realize a band-pass filter with a simple configuration by combining the elements constituting the trap with the elements determining the degree of coupling of the double-tuned circuit.

Next, details of the present invention will be explained based on examples. FIG. 4 is a circuit diagram of a main part of a high frequency tuned amplifier which is an embodiment of the present invention. In FIG. 4, 2 is an amplifying element, 13 is an output terminal, 14 is an output electrode of the amplifying element 2, 21, 23 is an impedance matching section, 22 is a double tuning section, 24, 25 is a tuning circuit, 26, 27, 28, 29, 31, 33,
34, 35, 36 are microstrip lines,
30 and 32 indicate coupling capacitors.

The impedance matching section 21 is formed by a microstripline 26 provided in series with respect to the signal and a microstripline 27 serving as an open stub inserted in parallel.
is formed by microstrip lines 35 and 36. The respective impedance matching sections 21 and 23 are provided to match the impedance of the double-tuned circuit 22 to the amplification element 2 and the load connected to the output terminal 13.

The double-tuned circuit 22 is composed of microstriplines 28, 29, 31, 33, and 34, of which the microstriplines 28 and 3 are
4 is a short stub, and 31 is an open stub. and microstripline 2
Widths and lengths of 8, 29, 33, and 34 are determined so that there is no loss in the transmission frequency band and desired selection characteristics are obtained in other bands.
These microstrip lines are provided on one side of the board, and the other side serves as a ground conductor.

The open stub microstrip line 31 forms the trap according to the invention and is connected to the capacitor 3 connecting the tuned circuits 24 and 25.
0 and 32, and the capacitors 30 and 3
Together with 2, it is an element that determines the degree of coupling of the double-tuned circuit.

This microstrip line 31 is open at one end, and its length is set to be (2n+1)×λ/4 with respect to the wavelength λ of the frequency to be trapped (however, n is 0). ,1,2,
3,…).

Since the open stub set in this way resonates at the above frequency, the capacitor 3
Viewed from the connection point of 0 and 32, it is the same as if a trap circuit was inserted. If this trap frequency is set higher than the transmission frequency band, the wavelength in the transmission frequency band is smaller than (2n+1)λ/4, so it becomes equivalently capacitive, and the microstrip line becomes capacitive. Since it is open, it has a different distributed capacitance between it and the ground conductor on the back side of the board, so by changing the width of this microstrip line 31,
The characteristic impedance changes and two tuned circuits 24
and 25, and it is possible to set the trap frequency and the coupling degree of the double-tuned circuit separately.

FIG. 5 shows another embodiment. In addition, in the same figure, reference numbers 2, 13, 14, 21, 23, 2
6, 27, 35, and 36 refer to the same elements as in the previous figure. 37, 38, 42, 43 are capacitors, 39, 40, 41 are microstrip lines, 44 is a double tuning circuit, and 45, 46 are tuning circuits.

The double tuning circuit 44 includes two tuning circuits 45 and 46.
The connection between them is provided by a microstrip line 40 with one end grounded. In this case, the length of the microstrip line 40 is set to be n×λ/2 with respect to the wavelength λ of the frequency to be trapped (where n is 1, 2, 3, . . . ).

The short stub set in this way resonates at the above frequency when viewed from the connection point between the microstrip lines 39 and 41, so it is the same as if a trap circuit had been inserted.
If this trap frequency is set lower than transmission frequency bands ₁ and ₂ , the wavelength in the transmission frequency band will be longer than 2n×λ/2, so it will equivalently become inductive. Furthermore, since this microstrip line has distributed capacitance between it and the ground conductor provided on the back side of the board, changing the width will change the characteristic impedance, and therefore the inductance seen as a lumped constant will change. Become. This inductance can change the degree of coupling of the double-tuned circuit 44, and the trap frequency and the degree of coupling of the double-tuned circuit can be set separately.

As described above, in the present invention, a capacitive or inductive microstrip line is provided as a trap element at the coupling part of a double-tuned circuit, and by changing its length and characteristic impedance, the band-pass characteristic can be improved. This provides the freedom to control both the trap frequency and the trap frequency, which reduces the number of parts, and since it uses a planar circuit, there is less variation in the trap frequency due to installation, making it possible to create a low-cost and compact band-pass filter with a trap. This is something that can be provided.

[Brief explanation of drawings]

Figure 1 is a circuit diagram of a conventional bandpass filter, Figure 2 is its characteristic diagram, Figure 3 is an equivalent circuit diagram of the circuit in Figure 1, and Figure 4 is an embodiment of the present invention. Circuit diagram, FIG. 5 is a circuit diagram of another embodiment. In the figure, 2 is an amplification element, 13 is an output terminal, 21,
23 is an impedance matching section, 22 is a double tuning circuit, 26, 27, 28, 29, 31, 33,
34, 35, 36 are microstrip lines,
30 and 32 indicate coupling capacitors.

Claims (1)

[Claims] 1. In a double-tuned circuit providing bandpass characteristics,
A microstrip line with one end open is provided in the capacitive circuit that determines the degree of coupling, the microstrip line is formed on one surface of the substrate, and a ground conductor surface is formed on the other surface of the substrate, Furthermore, the length of the microstrip line is determined by n being 0, 1, 2, . . . for the wavelength λ of the trap frequency.
1. A bandpass filter having a trap characterized in that the trap is set to (2n+1)×λ/4 when the trap is an integer. 2 In a double-tuned circuit that provides bandpass characteristics,
A microstrip line with one end short-circuited is provided in the inductive circuit that determines the degree of coupling, the microstrip line is formed on one side of the board, and a ground conductor plane is formed on the other side of the board, and The length of the microstrip line is determined by n being 0, 1, 2, . . . with respect to the wavelength λ of the trap frequency.
A bandpass filter having a trap, characterized in that the trap is set to n×λ/2, where n×λ/2 is an integer.