In-band-flat-group-delay type dielectric filter and linearized amplifier using the same

FIELD OF THE INVENTION

The present invention relates to an in-band-flat-group-delay type dielectric filter having a uniform group delay time, which mainly is used in high-frequency radio equipment utilizing a high frequency band and to a linearized amplifier using the same.

BACKGROUND OF THE INVENTION

Recently, many linearized amplifiers have come to be used in base station radio equipment for mobile communication systems to reduce the sizes of base stations.

FIG. 32

is a block diagram showing a feedforward amplifier as a typical example of linearized amplifiers. The feedforward amplifier shown in

FIG. 32

includes delay circuits

321

, directional couplers

322

,

323

, and

325

, a main amplifier

324

, an error amplifier

326

, an input terminal

327

, and an output terminal

328

. Main signals are input from the input terminal

327

and are amplified in the main amplifier

324

. In the signals amplified in the main amplifier

324

, distortion occurs and only distorted components are detected in a carrier cancellation loop. The feedforward amplifier is a circuit in which only the distorted components are eliminated, from the signals including the distortion, which has been amplified in the main amplifier

324

, in the distortion cancellation loop, and only signals including no distortion are extracted. The details of its operation are described in “High-Power GaAs FET Amplifiers” by John L. B. Walker (issued by Artech House (Boston, London), see 7.3.2 Linearized Amplifiers). In the carrier cancellation loop and the distortion cancellation loop, in order to allow the group delay times of the two signals divided in the directional coupler

323

to coincide exactly with each other and to synthesize them in the directional coupler

325

, strict and fine adjustment of the group delay times is required for the delay circuits

321

.

Conventionally, in a distortion compensating circuit in a linearized amplifier, for the purpose of adjusting group delay times, a delay device using a coaxial cable such as one with a diameter of about 2 cm and a length of at least 10 m has been used in general.

However, such a delay device is large and has a great insertion loss, which have been disadvantages. The great insertion loss requires the device to have a higher output power, thus causing various problems such as an increase in the size of equipment, a high power consumption, a further complicated configuration relating to radiation, or the like, which have been obstacles to obtaining small base station equipment. Furthermore, it is required to vary the physical length of a cable for carrying out the fine adjustment of the group delay time. Therefore, each time the length is varied, it is necessary to disconnect connectors and to cut the cable, resulting in a poor working efficiency, which has been a problem.

On the other hand, a dielectric filter mainly has been used for removing undesired signals as a bandpass filter or a band stop filter, and particularly, its amplitude transfer characteristics have received attention. Therefore, conventional dielectric filters have low losses, but a deviation in group delay time depending on frequencies is great. For this reason, it has been considered that the conventional dielectric filters cannot be used for delay devices providing uniform group delays. Moreover, it has been hardly intended to flatten both amplitude characteristics and group delay frequency characteristics at the same time. In addition, there has been no example of achieving both the low loss and the reduction in size using a dielectric.

SUMMARY OF THE INVENTION

The present invention is intended to provide an in-band-flat-group-delay type dielectric filter with a small size, a low loss, and uniform-group-delay frequency characteristics.

The present invention also is intended to provide a dielectric filter in which a fine adjustment of a group delay time can be carried out easily.

Furthermore, the present invention is intended to provide a small linearized amplifier using such a dielectric filter.

An in-band-flat-group-delay type dielectric filter according to a first basic configuration of the present invention includes a plurality of dielectric coaxial resonators, a coupling circuit comprising a combination of reactive elements, with which the respective dielectric coaxial resonators are coupled to one another, and input/output terminals connected to ends of the coupling circuit. The dielectric coaxial resonators coupled to the input/output terminals have a different characteristic impedance from that of the other inter-stage dielectric coaxial resonators. According to this configuration, a small filter with a low loss and uniform-group-delay frequency characteristics can be obtained. Therefore, for example, when a cable-type delay device used in a feedforward linearized amplifier or the like is replaced by the filter with the configuration described above, due to a lower loss, a load on the amplifier is reduced and a margin in heat radiation design can be obtained, and at the same time, the size of the amplifier can be reduced. Furthermore, broad-band characteristics can be obtained and thus uniform-group-delay frequency characteristics can be obtained together with the low-loss characteristics with a small amplitude deviation. In the above-mentioned configuration, it is preferred to set the characteristic impedance of the dielectric coaxial resonators coupled to the input/output terminals to be higher than that of the other inter-stage dielectric coaxial resonators.

In the above basic configuration, it is preferable that both deviations in group delay time and in amplitude between the input/output terminals fall within predetermined certain deviation values, respectively, at the center frequency and within a specified frequency band around the center frequency at the same time, and the minimum of the group delay time within a passband is at least one nanosecond.

In the above-mentioned basic configuration, preferably, the dielectric coaxial resonators coupled to the input/output terminals are half-wave dielectric resonators with their both ends opened. According to this configuration, the Q value indicating the performance of the resonators is high, thus obtaining the effects of reducing the size and loss.

In the above-mentioned basic configuration, preferably, the dielectric coaxial resonators coupled to the input/output terminals are quarter-wave dielectric resonators with their one ends short-circuited, and the inter-stage dielectric coaxial resonators are half-wave dielectric resonators with their both ends opened. According to this configuration, a slope parameter can be varied between the input/output stages and the interstages, thus facilitating the manufacture.

In the above-mentioned basic configuration, it is possible to allow the dielectric coaxial resonators coupled to the input/output terminals to have a different characteristic impedance from that of the other inter-stage dielectric coaxial resonators by using dielectric materials with different dielectric constants. According to this configuration, the characteristic impedance can be varied easily, multistage dielectric resonators can be obtained while excellent input/output matching is maintained, the broad-band characteristics can be obtained, and low-loss characteristics with a small amplitude deviation and uniform-group-delay frequency characteristics can be obtained.

The characteristic impedance of the dielectric coaxial resonators coupled to the input/output terminals may be made different from that of the inter-stage dielectric coaxial resonators by making diameter ratios of the dielectric coaxial resonators coupled to the input/output terminals and the inter-stage dielectric coaxial resonators different. According to this configuration, the resonators are allowed to have different characteristic impedances easily. Therefore, even when, for instance, dielectric ceramic materials with the same relative dielectric constant are used, the above-mentioned configuration can be achieved, resulting in an easier manufacture.

Furthermore, it is preferable that the above-mentioned basic configuration further includes a transmission line and a directional coupler. The coupling circuit is formed of capacitors, which are formed on a coupling board formed on a dielectric substrate, for coupling the dielectric coaxial resonators. An in-band-flat-group-delay type dielectric filter, which includes the coupling board and the dielectric coaxial resonators, and the directional coupler are combined via the transmission line to form one body. According to this configuration, the loss is reduced and the size reduction also can be achieved easily.

In this configuration, it is possible to construct the coupling circuit by forming capacitors on a first dielectric substrate, forming the directional coupler on a second dielectric substrate, and then combining the first and second dielectric substrates to form one body. According to this configuration, the coupling capacitors between the stages of the resonators and the directional coupler are formed on the same dielectric substrate, thus obtaining effects of enabling a simple manufacturing process and the reductions in size and in loss.

In the above mentioned basic configuration, it is possible to regulate the resonance frequencies of the dielectric coaxial resonators by providing metallic screw tuners positioned adjacent to and in parallel to open ends of the dielectric coaxial resonators and varying the distances between the screw tuners and the dielectric coaxial resonators. According to this configuration, the regulation operation is facilitated and thus the productivity is improved drastically since the filter is a multistage filter, and in addition, an accurate regulation is possible, thus achieving a higher performance.

Furthermore, in the above-mentioned basic configuration, the resonance frequencies of the dielectric coaxial resonators can be regulated by providing metal fittings for frequency regulation electrically connected to internal conductors of the dielectric coaxial resonators and metallic screw tuners positioned adjacent to and in parallel to the metal fittings, and varying the distances between the metal fittings and the screw tuners. According to this configuration, the regulation operation is facilitated and thus the productivity is improved drastically since the filter is a multistage filter, and in addition, an accurate regulation is possible, thus achieving a higher performance.

In the above-mentioned basic configuration, metallic screw tuners provided movably in a direction perpendicular to the open ends of the respective dielectric coaxial resonators are inserted into inner holes of the dielectric coaxial resonators via dielectrics or insulators, and by varying the insertion lengths, the resonance frequencies of the dielectric coaxial resonators can be regulated. According to this configuration, the regulation operation is facilitated and thus the productivity is improved drastically since the filter is a multistage filter, and in addition, an accurate regulation is possible, thus achieving a higher performance.

In any one of the above-mentioned configurations using the screw tuners, the screw tuners may be attached to a case, and may be formed from gold, silver, or copper or may have surfaces plated with gold, silver, or copper. According to this configuration, a high no-load Q value of the resonators can be maintained, thus obtaining filter characteristics with a low loss and a high performance.

Furthermore, the frequency may be regulated by attaching the screw tuners to the case with one ends of the respective screw tuners being exposed to the outside of the case, and regulating the positions of the screw tuners from the outside of the case. According to this configuration, the regulation operation is facilitated and thus the productivity is improved drastically since the filter is a multistage filter, and in addition, an accurate regulation is possible, thus achieving a higher performance. In addition, the whole can be shielded, thus obtaining an effect of being resistant to noise jamming.

The in-band-flat-group-delay type dielectric filter of the present invention can have a configuration in which a plurality of filter blocks formed of in-band-flat-group-delay type dielectric filters with the above-mentioned basic configuration are included and the plurality of filter blocks are cascaded with a transmission line having a characteristic impedance whose value is substantially the same as that of an input/output impedance. According to this configuration, the respective filters can be regulated separately, thus highly facilitating the regulation of the whole.

In this configuration, preferably, the plurality of filter blocks are separated by shielding cases individually. According to this configuration, the characteristics of each filter block can be found accurately and therefore the regulation is facilitated.

In the above-mentioned basic configuration, it is possible that the frequency band with a uniform group delay (hereinafter referred to as a “uniform-group-delay frequency band”) is within a passband in amplitude transfer characteristics and a variation in amplitude in the amplitude transfer characteristics within the uniform-group-delay frequency band is smaller than that in amplitude in the whole passband in the amplitude transfer characteristics outside the uniform-group-delay frequency band. In this configuration, it is possible that the minimum of insertion loss within the passband in the amplitude transfer characteristics falls within the uniform-group-delay frequency band. Moreover, in the above-mentioned basic configuration, it also is possible that a uniform-group-delay frequency band is within a passband in amplitude transfer characteristics and the center frequency of the uniform-group-delay frequency band is higher than that of the passband in the amplitude transfer characteristics. According to these configurations, further excellent characteristics that are desirable for a delay device can be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

In the above-mentioned basic configuration, it is possible that a uniform-group-delay frequency band is within a passband in amplitude transfer characteristics and the passband in the amplitude transfer characteristics has a width at least twice as wide as that of the uniform-group-delay frequency band. According to this configuration, the reduction in loss and uniform-group-delay frequency characteristics can be obtained and further excellent characteristics that are desirable for a delay device also can be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

In the above-mentioned basic configuration, it is possible that the frequency characteristics in group delay time have peak values at both edges of a passband in amplitude transfer characteristics and the peak value at the lower edge of the passband in the amplitude transfer characteristics is larger than that at the upper edge. It also is possible that a return loss within the uniform-group-delay frequency band has a ripple, and the minimum of the ripple within the uniform-group-delay frequency band is larger than that of ripple in a return loss outside the uniform-group-delay frequency band, and decreases from the center portion toward the both edges of the passband in the amplitude transfer characteristics. According to these configurations, further excellent characteristics that are desirable for a delay device can be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

An in-band-flat-group-delay type dielectric filter according to a second basic configuration includes a plurality of dielectric coaxial resonators, a coupling circuit comprising a combination of reactive elements, with which the respective dielectric coaxial resonators are coupled to one another, and input/output terminals connected to ends of the coupling circuit. Both deviations in group delay time and in amplitude between the input/output terminals fall within specified certain deviation values, respectively, at the same time at the center frequency and within a specified passband around the center frequency. At least one reactive element included in the coupling circuit is a variable reactive element. Thus, the group delay time within the passband can be varied.

According to this configuration, the group delay time can be varied continuously by the variable reactive element. Therefore, in a feedforward circuit in a linearized amplifier or the like, the efficiency of regulation is improved, and thus productivity and mass-productivity are improved.

The group delay time within the passband may be varied by: providing a plurality of dielectric coaxial resonators; connecting the respective adjacent dielectric coaxial resonators via at least two reactive elements connected in series; connecting a portion between the reactive elements and a ground via a variable reactive element; and varying the value of the variable reactive element.

In the above configuration, as the variable reactive element, a trimmer capacitor or a varactor diode can be used.

An in-band-flat-group-delay type dielectric filter according to a third basic configuration of the present invention includes a plurality of dielectric resonators, a main circuit comprising series coupling capacitors, with which the dielectric resonators are connected to one another, and an auxiliary circuit for coupling the main circuit with capacitors by bypass coupling. Both deviations in group delay time and in amplitude between input/output terminals fall within specified certain deviation values, respectively, at the same time at the center frequency and within a specified frequency band around the center frequency.

According to this configuration, the group delay frequency characteristics have no large peak in the vicinities of the edges of a passband and the uniform-group-delay frequency band is wide, thus achieving a number of group delays with a small number of stages.

In the above-mentioned third basic configuration, the following configuration can be obtained: two of the series coupling capacitors connect between the adjacent dielectric resonators; each one end of parallel bypass capacitors included in the auxiliary circuit is connected to a junction between the two of the series coupling capacitors; and the other ends of the adjacent parallel bypass capacitors are connected to be short circuited or via at least one of the series bypass capacitors.

In the third basic configuration, the following configuration also can be obtained: one of the series coupling capacitors connects between the adjacent dielectric resonators; each one end of parallel bypass capacitors included in the auxiliary circuit is connected to a junction between the series coupling capacitors; and the other ends of the adjacent parallel bypass capacitors are connected to be short circuited or via at least one of the series bypass capacitors.

In the above configuration, at least one of the parallel bypass capacitors may be opened. In addition, at least one of the series bypass capacitors may be short circuited.

In any one of the configurations according to the third basic configuration described above, the following configuration can be obtained. That is, the frequency characteristics in group delay have a peak value at the lower edge of a passband in amplitude transfer characteristics, and uniform-group-delay frequency characteristics within the passband. In a higher frequency band than the upper edge of the passband, the frequency characteristics in group delay frequency characteristics do not increase from a uniform group delay time within the passband but decrease.

A linearized amplifier of the present invention includes a dielectric filter with any one of the above-mentioned configurations, and a group delay time in a distortion compensating circuit is regulated by the dielectric filter. This configuration achieves the reductions in size of base station radio equipment and in power consumption, the simplification of configuration relating to radiation, and the like.

In the linearized amplifier with this configuration, the distortion compensating circuit can be designed as a feedforward type. According to this configuration, the in-band-flat-group-delay type dielectric filter is inserted into the main path in which a large current passes, thus further improving the effects of the reductions in size of base station radio equipment and in power consumption, the simplification of configuration relating to radiation, and the like.

In the linearized amplifier with the above-mentioned configuration, it is possible to set the uniform-group-delay frequency band width in the dielectric filter to be at least three times as wide as a required bandwidth of the amplifier. According to this configuration, the intermodulation distortion of third order or higher in the amplifier can be compensated, thus obtaining an amplifier causing a low distortion.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A

is a perspective view of an in-band-flat-group-delay type dielectric filter according to a first embodiment of the present invention, which is shown with an upper wall of its case being removed; and

FIG. 1B

is a plan view of the same.

FIG. 2

is an enlarged sectional view of an end portion of a half-wave coaxial dielectric resonator included in the dielectric filter shown in

FIGS. 1A and 1B

.

FIG. 3

is a schematic diagram of an equivalent circuit of the dielectric filter shown in

FIGS. 1A and 1B

.

FIG. 4A

is a graph showing transfer characteristics of the dielectric filter shown in

FIGS. 1A and 1B

; and

FIG. 4B

is a graph showing group delay frequency characteristics of the dielectric filter shown in

FIGS. 1A and 1B

.

FIG. 5

is a perspective view showing end portions of the coaxial dielectric resonators included in the dielectric filter shown in

FIG. 1

with metal fittings for frequency regulation being removed.

FIG. 6

is an enlarged sectional view showing an end portion of another example of the half-wave coaxial dielectric resonator included in the dielectric filter according to the first embodiment of the present invention.

FIG. 7A

is a graph showing transfer characteristics in one example of regulation of the dielectric filter according to the first embodiment of the present invention; and

FIG. 7B

is a graph showing group delay frequency characteristics in the same regulation example.

FIG. 8A

is a graph showing transfer characteristics in another example of regulation of the dielectric filter according to the first embodiment of the present invention; and

FIG. 8B

is a graph showing group delay frequency characteristics in the same regulation example.

FIG. 9A

is a graph showing transfer characteristics in a further example of regulation of the dielectric filter according to the first embodiment of the present invention; and

FIG. 9B

is a graph showing group delay frequency characteristics in the same regulation example.

FIG. 10A

is a graph showing transfer characteristics in still another example of regulation of the dielectric filter according to the first embodiment of the present invention; and

FIG. 10B

is a graph showing group delay frequency characteristics in the same regulation example.

FIG. 11A

is a graph showing transfer characteristics in yet another example of regulation of the dielectric filter according to the first embodiment of the present invention; and

FIG. 11B

is a graph showing return loss characteristics in the same regulation example.

FIG. 12

is a block diagram of a dielectric filter according to a second embodiment of the present invention.

FIG. 13A

is a plan view showing the dielectric filter according to the second embodiment of the present invention, which is shown with an upper wall of its case being removed; and

FIG. 13B

is a partial enlarged perspective view of the same.

FIG. 14

is a schematic diagram of an equivalent circuit of the dielectric filter shown in

FIGS. 13A and 13B

.

FIG. 15

is a perspective view of a dielectric filter included, as a part, in a feedforward amplifier according to a third embodiment of the present invention.

FIG. 16

is a perspective view of a dielectric filter according to a fourth embodiment of the present invention, which is shown with an upper wall and a part of side walls of its case being removed.

FIG. 17

is a schematic diagram of an equivalent circuit of the dielectric filter shown in FIG.

16

.

FIG. 18

is a graph showing transfer characteristics and group delay time of the dielectric filters according to the fourth embodiment and a fifth embodiment of the present invention.

FIG. 19

is a perspective view of the dielectric filter according to the fifth embodiment of the present invention, which is shown with an upper wall and a part of side walls of its case being removed.

FIG. 20

is a schematic diagram of an equivalent circuit of the dielectric filter shown in FIG.

19

.

FIG. 21

is a schematic diagram of an equivalent circuit in which a T-type connection of a trimmer capacitor and a coupling capacitor formed between dielectric coaxial resonators of the dielectric filter according to the fifth embodiment of the present invention is transformed to a Π-type connection.

FIG. 22

is a graph showing transfer characteristics in the case where Q values of variable capacitors in the dielectric filters according to the fourth and fifth embodiments of the present invention are taken as 100.

FIG. 23

is a schematic diagram of an equivalent circuit using a varactor diode and a choke coil as a variable capacitor in the dielectric filter according to the fifth embodiment of the present invention.

FIG. 24

is a perspective view of a dielectric filter according to a sixth embodiment of the present invention, which is shown with an upper wall and a part of side walls of its case being removed.

FIG. 25

is a schematic diagram of an equivalent circuit of the dielectric filter shown in FIG.

24

.

FIG. 26A

is a diagram showing the comparison in group delay frequency characteristics between a 14-stage dielectric filter according to the sixth embodiment of the present invention and a conventional 14-stage dielectric filter; and

FIG. 26B

is a diagram showing the comparison in group delay frequency characteristics between a 7-stage dielectric filter according to the sixth embodiment of the present invention and a conventional 14-stage dielectric filter.

FIG. 27

is a schematic diagram of an equivalent circuit in which parallel bypass capacitors in the dielectric filter according to the sixth embodiment of the present invention are partially opened.

FIG. 28

is a perspective view of a dielectric filter according to a seventh embodiment of the present invention, which is shown with an upper wall and a part of side walls of its case being removed.

FIG. 29

is a schematic diagram of an equivalent circuit of the dielectric filter according to the seventh embodiment of the present invention.

FIG. 30

is a schematic diagram of an equivalent circuit with short circuited series bypass capacitors in the dielectric filter according to the sixth embodiment of the present invention.

FIG. 31

is a schematic diagram of an equivalent circuit with partially opened parallel bypass capacitors in the dielectric filter according to the sixth embodiment of the present invention.

FIG. 32

is a block diagram of a conventional feedforward amplifier.

DETAILED DESCRIPTION OF THE INVENTION

FIRST EMBODIMENT

An in-band-flat-group-delay type dielectric filter according to a first embodiment of the present invention is described in detail with reference to the drawings as follows.

FIGS. 1A and 1B

show the inside of the dielectric filter according to the first embodiment, with the upper wall of a case

17

being removed. In

FIGS. 1A and 1B

, numeral

11

denotes input/output connectors. Numeral

12

indicates an alumina coupling board. Numerals

13

a

and

13

b

denote copper-plated electrodes forming coupling capacitors, which are formed on the coupling board

12

. Numeral

14

denotes quarter-wave coaxial dielectric resonators with a relative dielectric constant εr of

21

, which are coupled to the input/output connectors

11

. Numeral

15

indicates,half-wave coaxial dielectric resonators with a relative dielectric constant εr of

43

. Numeral

16

indicates gold-plated screw tuners for regulating a resonance frequency. Numeral

18

shown in

FIG. 1B

indicates silver-plated metal fittings for frequency regulation, which are provided for increasing loading capacitance between the screw tuners

16

and the half-wave coaxial dielectric resonators

15

.

With respect to the quarter-wave coaxial dielectric resonators

14

and the half-wave coaxial dielectric resonators

15

, their one end faces are aligned and their respective external conductors are grounded to the case

17

. The copper-plated electrodes

13

are electrically connected to internal conductors of the quarter-wave coaxial dielectric resonators

14

and the half-wave coaxial dielectric resonators

15

with solder or the like. To the copper-plated electrodes

13

b

at both ends of the alumina coupling board

12

, internal conductors of the input/output connectors

11

are connected with solder or the like.

FIG. 2

is an enlarged sectional view of an end portion, at the side on which the half-wave coaxial dielectric resonators

15

are not connected to the copper-plated electrodes

13

a

, of a half-wave coaxial dielectric resonator

15

included in the dielectric filter shown in FIG.

1

A. To an end of an internal conductor

15

a

of the half-wave coaxial dielectric resonator

15

, the metal fitting

18

for frequency regulation is connected and faces the screw tuner

16

. The screw tuner

16

is inserted into a screw hole provided in the case

17

serving as a ground, and is rotated to adjust the distance between the metal fitting

18

and the screw tuner

16

.

With respect to the in-band-flat-group-delay type dielectric filter with the configuration described above, its operation is described as follows.

FIG. 3

is a schematic diagram of an equivalent circuit of the in-band-flat-group-delay type dielectric filter according to the first embodiment shown in FIG.

1

. In

FIG. 3

, the respective parts corresponding to those in

FIG. 1

are indicated with the same numbers as in FIG.

1

. Numeral

31

denotes coupling capacitors formed of the electrodes

13

a

and

13

b

shown in FIG.

1

. In this way, the respective dielectric resonators

14

and

15

are coupled via coupling capacitors

31

, thus obtaining a multistage bandpass filter. In this specification, for example, as shown in

FIG. 3

, series capacitors coupling between input/output terminals

11

, between which the dielectric resonators

14

and

15

are connected, are referred to as “coupling capacitors”.

Characteristics of this filter are shown in

FIGS. 4A and 4B

. By optimizing the resonance frequencies of the dielectric resonators

14

and

15

and the values of the coupling capacitors

31

, the characteristics shown in

FIGS. 4A and 4B

can be obtained. In other words, a uniform-group-delay frequency band (indicated as a range B in

FIG. 4B

) is within a passband in amplitude transfer characteristics, thus obtaining flat characteristics in which the variation ΔB in amplitude in the transfer characteristics within the uniform-group-delay frequency band is smaller than the variations ΔA

1

and ΔA

2

in the passband in amplitude transfer characteristics outside the uniform-group-delay frequency band (i.e.ΔB<ΔA

1

and ΔB<ΔA

2

). Furthermore, by connecting the metal fitting

18

to the internal conductor

15

a

of the half-wave coaxial dielectric resonator

15

as shown in

FIG. 2

, the area for forming a capacitor between the internal conductor

15

a

of the dielectric resonator

15

and the screw tuner

16

increases, thus increasing the frequency variable range. In addition, the screw tuners

16

can be regulated from the outside of the case

17

and therefore the regulation of the filter is facilitated. Thus, desired characteristics can be obtained easily.

FIG. 5

is a perspective view showing end faces of the quarter-wave coaxial dielectric resonators

14

and the half-wave coaxial dielectric resonators

15

included in the in-band-flat-group-delay type dielectric filter according to the first embodiment of the present invention, with the metal fittings

18

being removed. The inner diameter of the dielectric resonators

14

in the input/output stages is smaller than that of the inter-stage dielectric resonators

15

. Therefore, it is possible to set the characteristic impedance of the dielectric resonators

14

in the input/output stages to be higher than that of the inter-stage dielectric resonators

15

. This enables broad-band characteristics to be obtained easily and thus uniform-group-delay frequency characteristics can be obtained together with low-loss characteristics with a small amplitude deviation. In addition, the same effect also can be obtained by allowing the characteristic impedance of the coaxial dielectric resonators

14

coupled to the input/output terminals to be different from that of the inter-stage coaxial dielectric resonators

15

, for example, by setting the dielectric constants of the dielectric resonators

14

and the dielectric resonators

15

to be

21

and

43

, respectively, as described above.

When the end faces of the half-wave coaxial dielectric resonators

15

are formed as shown in the sectional view illustrated in

FIG. 6

, frequency can be regulated more easily. The configuration shown in

FIG. 6

is different from that shown in

FIG. 2

in that the metal fitting

18

is omitted, a tuner supporter

61

formed of a dielectric with a low dielectric constant, such as “Teflon” or the like, is inserted into the inner hole of the dielectric resonator

15

, and a screw tuner

16

a

is inserted into a hollow portion. By inserting the screw tuner

16

a

into the inner hole of the dielectric resonator

15

via the tuner supporter

61

, the screw tuner

16

a

serving as a ground can form a capacitor with the internal conductor

15

a

of the dielectric resonator

15

without causing short circuit. Furthermore, since the capacitance is multiplied by a relative dielectric constant compared to that obtained in the case where the capacitor is formed via air, a frequency regulation range can be broadened. In addition, since the screw tuner

16

a

is held by and inside the tuner supporter

61

, the distance between the screw tuner

16

a

and the internal conductor

16

a

of the dielectric resonator

15

is constant, thus obtaining stable characteristics.

By regulating the resonance frequencies of the respective resonators and the values of coupling capacitors according to the above-mentioned configuration, the minimum of the insertion loss within the passband in the amplitude transfer characteristics can be obtained within a uniform-group-delay frequency band as shown in FIG.

7

A. Therefore, further excellent characteristics desirable for a delay device can be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

As shown in

FIGS. 8A and 8B

, it is possible to obtain the characteristics in which the uniform-group-delay frequency band is within the passband in the amplitude transfer characteristics and the center frequency fd of the uniform-group-delay frequency band is higher than the center frequency fc of the passband in the amplitude transfer characteristics. This enables further excellent characteristics desirable for a delay device to be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

As shown in

FIGS. 9A and 9B

, the following characteristics can be obtained. That is, the passband width Δf

1

in the amplitude transfer characteristics has a band width at least twice as wide as the uniform-group-delay frequency band width Δf

2

. This enables further excellent characteristics desirable for a delay device to be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

Similarly, as shown in

FIGS. 10A and 10B

, the following characteristics can be obtained. In the frequency characteristics of a group delay time, peak values of the group delay time are obtained at both edges of the passband in the amplitude transfer characteristics. In addition, the peak value at the lower edge of the passband in the amplitude transfer characteristics is larger than that at the upper edge. This enables further excellent characteristics desirable for a delay device to be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

Further, as shown in

FIGS. 11A and 11B

, the following characteristics can be obtained. That is, a return loss within a uniform-group-delay frequency band has a ripple and the minimum of the ripple is larger than that of the ripple in a return loss outside the band. In addition, the minimum becomes smaller from the center toward both edges of the passband in the frequency transfer characteristics. This enables further excellent characteristics desirable for a delay device to be obtained, thus obtaining a filter that can be produced and regulated easily and has a good balance between the amplitude characteristics and the delay characteristics.

As the screw tuners

16

and the metal fittings

18

for frequency regulation, examples that are gold-plated and silver-plated were described in the above. However, gold, silver, or copper may be used as their materials, or those plated with gold, silver, or copper also may be used.

SECOND EMBODIMENT

An in-band-flat-group-delay type dielectric filter according to a second embodiment of the present invention is described in detail with reference to the drawings as follows.

FIG. 12

is a block diagram of the in-band-flat-group-delay type dielectric filter according to the second embodiment of the present invention. Dielectric filters

121

have the same configuration as that of the in-band-flat-group-delay type dielectric filter according to the first embodiment. In this embodiment, two dielectric filters

121

are connected with a transmission line

122

.

FIG. 13A

shows the inside of an in-band-flat-group-delay type dielectric filter obtained by implementing the configuration illustrated by the block diagram shown in

FIG. 12

as a practical device, with an upper wall of its case being removed. Numeral

131

indicates a case, and numeral

132

a semi-rigid cable. This semi-rigid cable

132

is used as the transmission line

122

shown in FIG.

12

.

FIG. 13B

is a partial enlarged perspective view showing a portion including the semi-rigid cable

132

shown in FIG.

13

A.

The case

131

is formed of metal walls surrounding the dielectric filters

121

separated by the semi-rigid cable

132

so as to shield the dielectric filters

121

individually. The semi-rigid cable

132

has a characteristic impedance whose value is the same as that of the input/output impedance of the dielectric filters

121

.

With respect to the dielectric filter with the configuration as described above, its operation is described as follows.

FIG. 14

is a schematic diagram of an equivalent circuit of the in-band-flat-group-delay type dielectric filters according to the second embodiment shown in

FIGS. 12

,

13

A and

13

B. In

FIG. 14

, parts corresponding to those in

FIGS. 12

,

13

A and

13

B are indicated by the same numbers as in

FIGS. 12

,

13

A and

13

B. Numeral

31

indicates coupling capacitors formed of the electrodes

13

shown in

FIGS. 13A and 13B

. In this way, dielectric resonators

15

are coupled with the coupling capacitors

31

, thus obtaining a multistage bandpass filter.

As described above, a plurality of filter blocks are cascaded with the transmission line having a characteristic impedance whose value is the same as that of the input/output impedance, and thus the respective filters can be regulated separately. Similarly in this embodiment, modified examples with various configurations described in the first embodiment can be applied, and the characteristics shown in

FIGS. 4 and 7

to

11

obtained thereby also can be obtained. Thus, the regulation of the whole becomes very easy and the group delay time in the whole can be increased.

THIRD EMBODIMENT

A linearized amplifier according to a third embodiment of the present invention is described in detail with reference to the drawings as follows.

FIG. 15

is a perspective view showing the configuration of a part of a linearized amplifier, in which a dielectric filter

151

of the present invention is used as a delay circuit

321

included in the feedforward amplifier shown in

FIG. 32 and a

directional coupler

152

is used as the directional coupler

322

included in the feedforward amplifier shown in

FIG. 32

, which are combined to form one body. Numeral

153

denotes a transmission line, numeral

154

a quarter-wave transmission line, numeral

155

a termination, numeral

156

input/output connectors, and numeral

157

a directional coupling connector. The dielectric filter

151

and the directional coupler

152

are combined via the transmission line

153

to form one body. The configuration of the dielectric filter

151

may be the same as those of the above-mentioned embodiments and therefore is not shown in the figure.

The delay circuits

321

shown in

FIG. 32

are required to have group delay times equal to that of the main amplifier

324

or the auxiliary amplifier

326

. Generally, in the amplifiers

324

and

326

included in the feedforward amplifier, the group delay time is at least one nanosecond. Therefore, the group delay times of the dielectric filters

321

also are required to be at least one nanosecond.

In the feedforward amplifier, it is required to equalize group delay times strictly in the two paths and at the same time, small deviations in group delay time and in phase within a frequency band, i.e. flat characteristics, are required. In the present embodiment, practically satisfactory results were obtained when the deviations in group delay time and in phase are within ranges of ±10.5 ns and ±0.5°. These numbers depend on the circuit and system of the amplifier. When the deviations are reduced to obtain the flat characteristics, the regulation difficulty increases and the increase in number of stages of the dielectric resonators may be required in some cases.

When the in-band-flat-group-delay type dielectric filter according to the first or second embodiment is used as the delay circuit

321

in the distortion cancellation loop, signals are amplified in the amplifier and then the signals thus amplified are input into the filter. Therefore, a great effect of increasing the efficiency is obtained due to the decrease in loss. In addition, when the uniform-group-delay frequency band width in the dielectric filter is at least three times as wide as a required band width of the amplifier, the intermodulation distortion of third order or higher in the amplifier can be compensated, thus obtaining an amplifier causing a low distortion.

The same effect also can be obtained when a dielectric filter of the present invention is used as the delay circuit

321

in the carrier cancellation loop.

In the above-mentioned embodiment, capacitors are used for coupling the plurality of dielectric coaxial resonators. However, inductors or a coupling circuit formed of a combination of capacitors and inductors also can be used.

FOURTH EMBODIMENT

FIG. 16

shows the inside of a dielectric filter according to a fourth embodiment of the present invention, with an upper wall and a part of side walls of its case being removed. In

FIG. 16

, numeral

161

indicates input/output terminals, numeral

162

dielectric coaxial resonators, numeral

163

an alumina coupling board, numerals

164

a

and

164

b

copper-plated electrodes forming coupling capacitors, numeral

165

a trimmer capacitor, and numeral

166

a case.

The end faces of the dielectric coaxial resonators

162

are aligned and their respective external conductors are grounded to the case

166

. Internal conductors of the dielectric coaxial resonators

162

are electrically connected to the copper-plated electrodes

164

a

with solder or the like, respectively. Between the copper-plated electrodes

164

a

connected to the internal conductors of the dielectric coaxial resonators

162

, the trimmer capacitor

165

is connected. The copper-plated electrodes

164

b

at both ends of the alumina coupling board

163

are connected to internal conductors of the input/output terminals

161

.

With respect to the dielectric filter with the configuration as described above, its operation is described as follows.

FIG. 17

is a schematic diagram of an equivalent circuit of the dielectric filter according to the fourth embodiment of the present invention. In

FIG. 17

, the same parts as those in

FIG. 16

are indicated by the same numbers as in FIG.

16

. Numeral

171

indicates coupling capacitors on the input/output sides formed by the copper-plated electrodes

164

b

shown in FIG.

16

. In this way, the dielectric coaxial resonators

162

are coupled with the coupling capacitors

171

, respectively, thus obtaining a bandpass filter.

FIG. 18

shows transfer characteristics of the filter when the inter-stage trimmer capacitor

165

is varied. In this way, when the trimmer capacitor

165

is varied, the passband width in the filter varies, thus varying the group delay time accordingly.

As can been seen from

FIG. 18

, the peaks of the group delay time indicated by the curved line

182

are in the vicinities of the edges of the passband in the transfer characteristics indicated by the curved line

181

. Within a desired band width

183

between the peaks, the group delay time is substantially flat at smaller values than those at the peaks. The transfer characteristics when the passband is broadened is indicated by the curved line

184

and the group delay time in this case is indicated by the curved line

185

. When the passband is broadened, the interval between the peaks of the group delay time also is widened and the flat group delay time within the desired band width

183

is decreased, thus reducing the group delay time.

As described above, by varying the trimmer capacitor

165

between the dielectric coaxial resonators

162

, the passband can be broadened or narrowed, and thus the group delay time can be varied.

FIFTH EMBODIMENT

A dielectric filter according to fifth embodiment of the present invention is described with reference to the drawings as follows.

FIG. 19

shows the inside of a dielectric filter according to the fifth embodiment of the present invention, with an upper wall and a part of side walls of its case being removed. In

FIG. 19

, numeral

191

denotes input/output terminals, numeral

192

dielectric coaxial resonators, numeral

193

an alumina coupling board, numeral

194

a

and

194

b

copper-plated electrodes forming coupling capacitors, numeral

195

a trimmer capacitor, and numeral

196

a case.

The end faces of the dielectric coaxial resonators

192

are aligned and their respective external conductors are grounded to the case

196

. Internal conductors of the dielectric coaxial resonators

192

are electrically connected to the copper-plated electrodes

194

a

with solder or the like, respectively. Between a ground and a copper-plated electrode

194

c

positioned between the copper-plated electrodes

194

a

connected to the internal conductors of the dielectric coaxial resonators

192

, the trimmer capacitor

195

is connected. The copper-plated electrodes

194

b

at both ends of the alumina coupling board

193

are connected to internal conductors of the input/output terminals

191

.

With respect to the dielectric filter with the configuration as described above, its operation is described as follows.

FIG. 20

is a schematic diagram of an equivalent circuit of the dielectric filter according to the fifth embodiment of the present invention. In

FIG. 20

, the same parts as those in

FIG. 19

are indicated by the same numbers as in FIG.

19

. Numeral

201

indicates coupling capacitors on the input/output sides, which are formed of the copper-plated electrodes

194

b

positioned at both ends of the alumina coupling board

193

and the copper-plated electrodes

194

a

connected to the inner conductors of the dielectric coaxial resonators

192

. Numeral

202

denotes inter-stage coupling capacitors formed of the copper-plated electrodes

194

a

connected to the internal conductors of the dielectric coaxial resonators

192

and the copper-plated electrode

194

c

connected to the trimmer capacitor

195

. In this way, the dielectric coaxial resonators

192

are coupled with the coupling capacitors

201

on the input/output sides and the inter-stage coupling capacitors

202

, respectively, thus obtaining a bandpass filter.

The T-type circuit, as shown in

FIG. 20

, of the trimmer capacitor

195

connected to a ground from a portion between the coupling capacitors

202

can be transformed into a Π-type circuit as shown in

FIG. 21

by a transformation of the equivalent circuit. The capacitance value Cl of the inter-stage capacitor

211

shown in

FIG. 21

can be expressed by the following formula:

C

1=(

Cb

)

2

/(

Ca

+2

C

),

wherein Ca represents a capacitance value of the trimmer capacitor

195

and Cb a capacitance value of the inter-stage coupling capacitors

202

shown in FIG.

20

. This means that by varying the trimmer capacitor

195

, the inter-stage coupling capacitors are varied. Thus, the group delay time can be varied as in the fourth embodiment.

As described above, according to the present embodiment, by providing a variable capacitor in parallel to the ground from the series capacitors for coupling the dielectric coaxial resonators and allowing the capacitor to be varied, the group delay time can be varied continuously. Even when the variable capacitor is replaced by a variable inductor, the group delay time also can be varied.

FIG. 22

shows the transfer characteristics of the circuits shown in

FIGS. 17 and 20

in the case of a variable capacitor with a Q value of 100, which indicates the performance of circuit parts, and capacitors other than the variable capacitor with a Q value of 800. The line indicated by numeral

221

shows the characteristics of the circuit shown in FIG.

17

and the line indicated by numeral

222

shows the characteristics of the circuit shown in FIG.

20

. By positioning the variable capacitor in parallel, the insertion loss characteristics are not deteriorated greatly even when the Q value of the variable capacitor is low.

Since the group delay time can be varied continuously, in a feedforward circuit of a linearized amplifier or the like, the working efficiency of the regulation is increased, thus improving the productivity and mass-productivity.

In the above, the trimmer capacitor was used as the variable capacitor. However, the same effect also can be obtained when, as shown in

FIG. 23

, a varactor diode

231

is used to vary the voltage applied to a choke coil

232

, thus varying the capacitance between a portion between the coupling capacitors

202

and the ground.

SIXTH EMBODIMENT

In the dielectric filter with the above-mentioned configuration, the group delay frequency characteristics has high peaks in the vicinities of the edges of the passband and the band width between the peaks in which the group delay time is uniform is not so wide. Therefore, when a wide band width is desired, the number of stages is increased, thus increasing loss. The dielectric filter according to the present embodiment is characterized in that a number of group delays can be obtained in a desired band width using a small number of stages.

FIG. 24

is a perspective view showing a dielectric filter according to a sixth embodiment of the present invention, with its upper cover and a front face of a case

248

being removed. In

FIG. 24

, numeral

241

indicates input/output terminals, numeral

242

half-wave dielectric resonators with their ends opened, numeral

243

an alumina coupling board, numerals

244

to

247

copper-plated electrodes forming capacitors, and numeral

248

a case. The end faces of the dielectric resonators

242

are aligned and their respective external conductors are grounded to the case

248

. The copper-plated electrodes

244

are electrically connected to internal conductors of the dielectric resonators

242

with solder or the like, respectively. The copper-plated electrodes

245

are positioned between the copper-plated electrodes

244

and the copper-plated electrodes

246

are positioned so as to form parallel capacitors with the copper-plated electrodes

245

. The copper-plated electrodes

247

positioned outside the copper-plated electrodes

244

at both ends are connected to internal conductors of the input/output terminals

241

.

With respect to the dielectric filter with the configuration as described above, its operation is described as follows.

FIG. 25

is a schematic diagram of an equivalent circuit of the dielectric filter showing the sixth embodiment of the present invention. In

FIG. 25

, the same parts as those in

FIG. 24

are indicated with the same numbers as in FIG.

24

. Numeral

251

indicates inter-stage coupling capacitors formed of the copper-plated electrodes

244

and the copper-plated electrodes

245

shown in FIG.

24

. Numeral

252

denotes parallel bypass capacitors formed of the copper-plated electrodes

245

and the copper-plated electrodes

246

. Numeral

253

indicates series bypass capacitors formed between the respective copper-plated electrodes

246

. Numeral

254

denotes input/output capacitors formed of the copper-plated electrodes

244

and the copper-plated electrodes

247

.

As is apparent from the above description, in this specification, for example, in

FIG. 25

, the coupling capacitors between the dielectric resonators

242

are referred to as “inter-stage coupling capacitors”. Similarly, the coupling capacitors between the dielectric resonators

242

at both ends and the input/output terminals

241

, respectively, are referred to as “input/output capacitors”. Furthermore, the capacitors connected from portions between the coupling capacitors (including inter-stage coupling capacitors and input/output capacitors) to portions between the other coupling capacitors are referred to as “bypass coupling capacitors”. Particularly, the bypass coupling capacitors arranged in parallel directly from portions between the coupling capacitors are referred to as “parallel bypass capacitors” and the capacitors connecting the respective parallel bypass capacitors as “series bypass capacitors”. Moreover, the coupling via a bypass coupling capacitor is referred to as “bypass coupling”.

As shown in

FIG. 25

, the dielectric resonators

242

are connected in parallel to a main line formed of the inter-stage coupling capacitors

251

and the input/output capacitors

254

, thus obtaining a bandpass filter. A pole is provided on the lower band side in a passband by a sub line formed of the parallel bypass capacitors

252

and the series bypass capacitors

253

.

Generally, in a dielectric filter, a group delay time is specified according to an amplifier system and a small deviation in group delay time within a frequency band, i.e. a flat in-band group delay time is required. In order to increase the group delay time while maintaining the deviation in the in-band group delay time, it is necessary to increase the number of stages in the filter. Furthermore, in order to broaden the frequency band with a uniform deviation in group delay time while maintaining the group delay time, it is required to increase the number of stages. However, the increase in the number of stages results in an increased loss.

FIG. 26A

shows the comparison between the group delay frequency characteristics of a 14-stage dielectric filter according to the present invention and those of a conventional 14-stage dielectric filter. When compared to the group delay frequency characteristics of the conventional dielectric filter indicated by the curve

261

, the group delay frequency characteristics of the 14-stage dielectric filter of the present invention, indicated by the curve

262

, having the same number of stages as that of the conventional one, have a lower peak on the higher frequency band side in the frequency band, and thus a broader uniform-group-delay-time band width is obtained. As shown in

FIG. 26B

, in order to obtain the characteristics indicated by the curve

263

with the same band width and the same group delay time as those of the group delay frequency characteristics (indicated by the curve

261

) of the conventional dielectric filter, the dielectric filter according to the present invention requires only 7 stages and thus the number of the stages can be reduced considerably, thus achieving the reductions in filter size and in loss.

In the group delay frequency characteristics of the dielectric filter according to the present invention, it also is possible to eliminate the peak on the higher frequency band side in the frequency band by regulation and thus to broaden the frequency band with a uniform deviation in group delay time.

FIG. 27

shows a circuit in which the same characteristics as those obtained in the circuit shown in

FIG. 25

can be obtained. In the circuit shown in

FIG. 25

, corresponding to the required center frequency, frequency band, group delay time, deviation in the group delay time, or the like, the capacitors such as the inter-stage coupling capacitors

251

, the parallel bypass capacitors

252

, the series bypass capacitors

253

, the input/output capacitors

254

, or the like are regulated. However, a part of the parallel bypass capacitors

252

may be regulated to have a very small value depending on the desired characteristics. In such a case, as shown in

FIG. 27

, it is possible to omit very small parallel bypass capacitors

252

and to open the portions where the parallel bypass capacitors

252

thus omitted were positioned. The omission of the parallel bypass capacitors

252

enables two successive series inter-stage coupling capacitors

251

to be replaced by one inter-stage coupling capacitor

251

. Thus, while the same characteristics can be obtained, the number of components can be reduced.

FIG. 27

shows the case where some of the parallel bypass capacitors

252

are omitted. However, the same characteristics also can be obtained when some of the series bypass capacitors

253

are omitted.

In the above-mentioned embodiment, the half-wave dielectric resonators with both ends opened were used as the dielectric resonators

242

. However, quarter-wave dielectric resonators with their ends short-circuited may be used in order to obtain the same characteristics.

SEVENTH EMBODIMENT

A seventh embodiment of the present invention is described with reference to the drawings as follows.

FIG. 28

is a perspective view showing a dielectric filter according to the seventh embodiment of the present invention, with its upper cover and a front face of a case

248

being removed. In

FIG. 28

, numerals

281

to

283

indicate copper-plated electrodes forming capacitors, and the same parts as those in

FIG. 24

are indicated with the same numerals as in FIG.

24

. The copper-plated electrodes

281

are electrically connected to internal conductors of dielectric resonators

242

with solder or the like, respectively. The copper-plated electrodes

282

are positioned so as to form parallel capacitors with the copper-plated electrodes

281

. The copper plated electrodes

283

positioned outside the copper-plated electrodes

281

at both ends are connected to internal conductors of input/output terminals

241

.

The configuration shown in

FIG. 28

is different from that shown in

FIG. 24

in that no copper-plated electrode is provided between the copper-plated electrodes

281

.

FIG. 29

shows an equivalent circuit of the dielectric filter shown in

FIG. 28

illustrating the seventh embodiment of the present invention. In

FIG. 29

, the same parts as those in

FIG. 28

are indicated with the same numerals as in FIG.

28

. Numeral

291

indicates inter-stage coupling capacitors formed between the respective copper-plated electrodes

281

shown in FIG.

28

. Numeral

292

denotes parallel bypass capacitors formed of the copper-plated electrodes

281

and the copper-plated electrodes

282

. Numeral

293

indicates series bypass capacitors formed between the respective copper-plated electrodes

282

. The equivalent circuit shown in

FIG. 29

is different from that shown in

FIG. 25

in that the two inter-stage coupling capacitors between the dielectric resonators

242

are reduced to one and the parallel bypass capacitors are connected to points at which the series capacitors and the dielectric resonators

242

are connected.

According to the configuration as described above, while the same characteristics as those of the circuit shown in

FIG. 25

are maintained, the numbers of the inter-stage coupling capacitors, parallel bypass capacitors, and series bypass capacitors are reduced, thus reducing the regulation difficulty.

With respect to the regulation method of changing the characteristics with peaks on both sides to the characteristics with one peak on only one side in group delay time characteristics by providing a pole, in the transfer characteristics described above, theoretical studies have not been completed, but it is possible to obtain target characteristics by varying the circuit constants using a circuit simulator.

The element values calculated by the circuit simulator have the following tendencies. In the circuit shown in

FIG. 29

, toward the center from the input/output terminals

241

, the resonance frequency of the dielectric resonators

242

decreases and the capacitance values of the coupling capacitors and the parallel bypass capacitors decrease. The capacitance value of the series bypass capacitors increases toward the center. In some cases, however, these tendencies may not hold depending on the specifications and regulation of filters. In the circuit shown in

FIG. 25

, these tendencies do not hold due to the transformation from T type to Π type (Y-Δtransformation) in the circuit shown in FIG.

29

.

FIG. 30

shows a circuit in which the same characteristics as those obtained in the circuit shown in

FIG. 29

can be obtained. In the circuit shown in

FIG. 29

, the capacitors such as the inter-stage coupling capacitors

291

, the parallel bypass capacitors

292

, the series bypass capacitors

293

, the input/output capacitors

254

, and the like are regulated according to the desired center frequency, frequency band, group delay time, variation in the group delay time, and the like, but the series bypass capacitors

293

may be regulated to have very high values depending on the desired characteristics. In such a case, as shown in

FIG. 30

, it is possible to omit very large series bypass capacitors

293

and to allow the portions where the very large series bypass capacitors

293

thus omitted were positioned to be short-circuited. This allows the number of components to be reduced while the same characteristics can be obtained, thus reducing the regulation difficulty. In addition, as shown in

FIG. 31

, the same characteristics also can be obtained by omitting minute parallel bypass capacitors

282

and opening the portions where they were positioned. Consequently, the number of components can be reduced further and thus the regulation difficulty can be reduced.

In the respective embodiments described above, the alumina coupling board was used as the coupling board. However, the coupling board is not limited to this and, for example, a glass-epoxy board or the like also can be used, which can reduce the cost.

Examples using the copper-plated electrodes as the electrodes were described in the above, but the electrodes are not limited to those. For example, solder can be used, which can reduce the cost.

Furthermore, in the respective embodiments described above, the capacitors are obtained by using gaps between copper-plated electrodes, but are not limited to those. For instance, capacitors of alumina whose upper and lower surfaces are plated with copper, or chip capacitors can be used. The use of alumina capacitors provides protection against discharges occurring between electrodes when a large current is input. The use of the chip capacitors improves the mass-productivity.

The above descriptions mainly were directed to examples using capacitors as reactive elements. However, the reactive elements are not limited to the capacitors, and for example, inductors can be used.

As described above, the in-band-flat-group-delay type dielectric filter of the present invention is formed of dielectric resonators and capacitors or inductors, and is a bandpass dielectric filter having a frequency band with uniform group delay time in resonance frequencies. Therefore, for example, when a cable-type delay device used in a feedforward linearized amplifier or the like is replaced by the dielectric filter of the present invention, great effects are provided in that due to a reduced loss, the load on the amplifier can be reduced and allowance in heat radiation design can be provided. In addition, the size reduction also can be achieved.

Moreover, the linearized amplifier of the present invention employs an in-band-flat-group-delay type dielectric filter of the present invention, thus particularly enabling the reduction in size of radio equipment in mobile communication base stations, the reduction in power consumption, simplification of a configuration relating to radiation, and the like. Consequently, a small base station equipment can be obtained.

The invention may be embodied in other forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed in this application are to be considered in all respects as illustrative and not limiting. The scope of the invention is indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.

Number	Date	Country
11-207633	Jul 1999	JP
11-297776	Oct 1999	JP
2000-068304	Mar 2000	JP

Number	Name	Date	Kind
4223287	Nishikawa et al.	Sep 1980	A
5969584	Huang et al.	Oct 1999	A
6081175	Duong et al.	Jun 2000	A
6262639	Shu et al.	Jul 2001	B1

Number	Date	Country
402094901	Apr 1990	JP
06260807	Sep 1994	JP
11-68409	Mar 1999	JP

In-band-flat-group-delay type dielectric filter and linearized amplifier using the same

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (3)

US Referenced Citations (4)

Foreign Referenced Citations (3)

Non-Patent Literature Citations (1)