JPH0828604B2 - Shared transmission device - Google Patents

Description

Description: (a) Field of Industrial Application The present invention relates to a transmission common device that synthesizes a plurality of transmission signals and transmits them to a common output line or antenna.

(B) Background of the Invention In recent years, cellular systems have come into wide use in mobile communication systems such as car phones using the 800 MHz band. In such a cellular system,
The radius of the cell (radio zone) and the radio channel in the cell are set according to the traffic.

In mobile communication systems such as the above-mentioned car telephones, in which the number of users has been rapidly increasing recently, it is necessary to reduce the cell radius and increase the number of base stations. Along with that,
There is a further demand for downsizing, loss reduction, and cost reduction of the transmission sharing device used for the base station.

(C) Conventional Technique The transmission sharing device used in the above-described base station is mainly composed of a plurality of channel filters and a synthesizing unit for synthesizing output signals of the respective channel filters.

As a channel filter, a resonator having a high Q such as a cavity resonator or a semi-coaxial cavity resonator has been conventionally used. Recently, a TE ₀₁ δ-mode dielectric resonator having a high Q is used as in the cavity resonator and the semi-coaxial cavity resonator, and the size is reduced as a whole.

As the combining unit, a combining circuit (so-called junction unit) using a coaxial cable or a waveguide is used, and the main part of the shared transmission device is configured by connecting the combining circuit to the output part of the resonator.

(D) Problem to be Solved by the Invention However, even if the dielectric resonator is used as the channel filter, the entire transmission sharing apparatus including the combining unit is still large and has a small cell radius. It was not suitable as a transmission sharing device installed in a station.

An object of the present invention is to provide a transmission sharing apparatus in which the resonator used as a channel filter is further downsized, and further the transmission sharing apparatus including the combining unit is downsized, reduced in loss, and reduced in cost. is there.

(E) Means for Solving the Problems The transmission sharing device of the present invention is provided with a plurality of signal input coupler insertion holes and a signal output coupler insertion hole, respectively, and a plurality of TM modes for respectively passing bands of specific channels. The dielectric resonator is a channel filter unit in which at least the insertion holes for the signal output couplers are arranged in parallel with each other, and two substrates are laminated, and a transmission electrode is provided inside the dielectric resonator. A junction unit in which a signal output coupler is projected to the outside of the substrate and a branch line for synthesizing the signal of the signal output coupler is formed by the transmission electrode, and a conductor of the output section is connected to the synthesis point is formed. Inserting the signal output connector of the junction unit into the signal output connector insertion hole of the channel filter unit, Characterized in that to bind the junction unit to the knit.

(F) Operation The transmission sharing device of the present invention is roughly divided into a channel filter unit and a junction unit. Each channel filter of the channel filter unit includes an insertion hole for a signal input coupler and an insertion hole for a signal output coupler, and each of the plurality of channel filters passes a band of a specific channel.
The channel mode filter unit is composed of TM mode dielectric resonators, and the plurality of TM mode dielectric resonators are arranged side by side with at least the signal output coupler insertion holes on the same plane. On the other hand, in the junction unit, a signal output coupler is formed so as to project from the surface of the circuit board, and a branch line composed of a transmission line that combines the output of the signal output coupler is formed on the circuit board.

The junction unit is coupled to the channel filter unit configured as described above to configure one transmission sharing device.

When the transmission sharing apparatus of the present invention is used as a transmission sharing apparatus for a cellular base station, the transmission power is relatively low as the cell radius has been reduced in recent years, so that the dielectric resonator having a small power capacity is small. Can be used. Generally, TM mode dielectric resonators such as TM ₀₁₀ and TM ₁₁₀ are
_{01 Although} the Q is slightly lower than that of the δ mode dielectric resonator,
When miniaturizing the dielectric resonator as described above, the Q of the TM mode dielectric resonator can be kept higher than that of the TE mode dielectric resonator. Therefore, the channel filter unit has a smaller size and lower insertion loss.

In addition, since the signal output coupler that is coupled to the output of each dielectric resonator of the channel filter unit is integrally formed in the junction unit, it is possible to reduce the size of the transmission common by integrating it with the channel filter unit. The device can be configured.

(G) Embodiment The structure of the transmission sharing apparatus according to the first embodiment of the present invention is shown in FIGS.

FIG. 1 is a perspective view showing a state in which a channel filter unit and a junction unit are separated from each other, and FIG. 2 is a perspective view of an entire transmission common device in which both are integrated. In FIG. 1, 100 is a channel filter unit and 101 is a junction unit. Channel filter unit
In the figure, 100 is composed of a box-shaped metal case 1 having an opening at the top and eight TM mode dielectric resonators F1 to F8 housed therein. These dielectric resonators F1 to F8 are composed of a metallized hexahedral ceramic cavity and a prismatic internal dielectric provided therein. On the upper surface of each of the dielectric resonators F1 to F8 in the drawing, an insertion hole for a signal input coupler and an insertion hole for a signal output coupler are provided, which are indicated by Hi and Ho, respectively. Further, screw holes 2 to 13 for mounting the junction unit 101 are provided around the opening of the case 1.

The junction unit 101 shown in FIG.
It is composed of a single ceramic substrate, a branch line formed between the two ceramic substrates, a signal input connector, a signal output connector and an input / output connector. In the figure, reference numerals 15 and 16 denote ceramic substrates, and eight signal input connectors IN1 to IN8 and OU
One signal output connector indicated by T is attached. In addition, the channel filter unit 10
Holes 22 to 33 for screwing to 0 are formed.

The channel filter unit 100 and the junction unit 101 are connected as shown in FIG. 2 to form an 8-channel shared transmission device.

Next, the structure of one dielectric resonator used in the channel filter unit is shown in FIGS.

FIG. 3 is an exploded perspective view thereof. In the figure, reference numeral 50 denotes a metallized outer surface, and a prismatic internal dielectric 51 inside.
Are integrally molded ceramic bodies, and reference numerals 53 and 55 are ceramic plates whose inner surfaces are metallized, and they are integrated with the ceramic body 50 to form a ceramic cavity. It should be noted that round holes Hi and Ho for inserting the signal input coupler and the signal output coupler are formed on the upper surface of the ceramic body 50.

FIG. 4 is a central sectional view of one dielectric resonator after assembly. As shown in the figure, a cavity shielded by the electrodes 52 formed on the outer surface of the ceramic body 50 and the electrodes 54, 56 formed on the inner surfaces of the ceramic plates 53, 55 is formed. By the action of 51 TM
_It operates as a _110- mode dielectric resonator.

Next, the structure of the junction unit is shown in FIGS. 5 and 6 (A) to (C).

FIG. 5 shows a branch line formed on the upper surface of the ceramic plate 15, particularly a branch line formed of a transmission line. The portion indicated by 45 in the figure is a so-called triplate type transmission line.

6 (A) to (C) are AA and B- shown in FIG.
It is a fragmentary sectional view of the whole junction unit in a B and CC section. FIG. 3A is a sectional view of a transmission line portion (A-A portion in FIG. 5). The ceramic substrate 15 has electrodes 41, 41 formed on the front and back surfaces of a ceramic plate 40, and the other ceramic substrate 16 also has electrodes 43, 43 formed on the front and back surfaces of the ceramic plate 42. A groove is formed at a predetermined position of the ceramic substrate 15, and the dielectric 44 is formed along the groove.
And the electrode 45 is formed on the upper surface thereof. This electrode 45
Is the electrode 41 of the ceramic substrate 15 and the electrode of the ceramic substrate 16
Together with 43, a triplate type transmission line is constructed.

FIG. 6 (B) is a sectional view of a portion (a portion BB in FIG. 5) where the signal output coupler is provided. As shown in the figure, a through hole is formed at a predetermined position of the ceramic substrate 15, a coupling probe (signal output coupler) 17 is attached to the dielectric 44 and the electrode 45, and the tip end thereof projects below the ceramic substrate 15. ing.

FIG. 6C is a sectional view of the output connector portion (portion CC in FIG. 5). An opening is formed in the ceramic substrate 16 at this portion, and the output connector OUT is connected to the ceramic substrate 1
Attached to the upper surface of 6 and its central conductor 1
8 is connected to electrode 45.

Further, through holes are formed in the ceramic substrates 15 and 16 at the mounting positions of the respective input connectors, and the central conductor of each of the input connectors serves as a signal input connector such as a coupling probe or a coupling group at the bottom of the substrate 15. Protruding to.

By fixing the junction unit configured as described above to the channel filter unit by fixing, the coupling probe 17 is inserted in the insertion hole for the signal output coupler of each dielectric resonator or is it protruding to the bottom of the junction unit? The channel center conductor of each signal input connector is inserted into the signal input connector insertion hole of each dielectric resonator. Therefore, the signal of each channel input from the signal input connector is input to the corresponding dielectric resonator, and the signal generated in the signal output coupler is power-combined by the branch line 45 formed of the transmission line and output from the output connector OUT. Is output.

In the branch line shown in FIG. 5, the electrical length from each output of the dielectric resonator (equivalent short-circuit plane of the resonator) to the first branch point a or b is an odd multiple of 1/4 wavelength. Is set. Further, the electrical length from the branch points a and b to the second branch point (the point where the central conductor of the output connector OUT is connected) is set to be an integral multiple of 1/2 wavelength. By configuring the branch line in this way, the impedance of the dielectric resonator seen from each branch point becomes very large at the frequency of the design wavelength, and the transmission power of the own channel is fed from the output connector with almost no loss.

The configuration of the transmission sharing apparatus according to the second embodiment is shown in FIGS. 7 (A) and (B) to FIG.

7 (A) and 7 (B) are perspective views of a 32-channel transmission common device, FIG. 7 (A) is a view from the signal input connector side, and FIG. 7 (B) is a view from the signal output connector side. In both figures, IN1 to IN32 are signal input connectors, and 32 input connectors corresponding to the number of channels are arranged on the same surface. One output connector OUT is provided on the side opposite to the mounting surface of the plurality of input connectors, as shown in FIG. Also, 60, 61, 62, 6 are provided on the four side surfaces other than the surface on which the signal input connector and output connector are formed.
Multiple air cooling fans, such as 3,64, are installed.

FIG. 8 is a schematic plan view showing the structure of the main part inside the transmission sharing apparatus, and FIG. 9 is a schematic cross-sectional view of the entire apparatus as seen from DD in FIG. In FIG. 8, F1 to F32 are TMs that pass the bands of the respective assigned channels.
It is a mode dielectric resonator. Further, JUa to JUh are junction units each having a branch line formed of a transmission line formed on a substrate, and combine four resonator outputs respectively. For example, the junction unit JUa combines the outputs of the resonators F1, F3, F9 and F11 at point a. Also, for example, the junction unit JUh is a resonator F22, F2
4, F30 and F32 outputs are combined at point h. The outputs of each of these junction units are combined by branch lines JU1 and JU2 composed of a coaxial cable or the like and supplied to circulators C1 and C2, respectively. Circulator C
Dummy loads R1 and R2 are respectively connected to 1 and C2, and the outputs of the branched lines JU1 and JU2 are combined and led to the output connector OUT.

The branch lines of the junction units JUa to JUh are set such that the electrical length from each resonator to the branch point is an odd multiple of 1/4 wavelength. Also, in the branch lines JU1 and U2 that combine the output of each junction unit,
Electrical length from junction unit to branch points i and j is 1
It is set to be an integral multiple of / 2 wavelength. By configuring the branch line in this way, the impedance of other resonators from each branch point becomes very large at the frequency of the set wavelength, and the transmission power of the local channel is fed to the circulators C1 and C2 with almost no loss. To be done. Similarly, another transmitter (circuit that supplies the channel filter with transmit power)
The amount of coupling attenuation with and becomes large, and the interference between transmitters becomes small.

In FIG. 9, the internal structure of the resonator F4 is shown. Here, 70 is a ceramic cavity, and 71 is a columnar internal dielectric integrally formed between the bottom surface and the top surface of the cavity, which constitutes a TM mode dielectric resonator. 72 and 73 are a signal input coupling loop and a signal output coupling loop for this resonator. 32 channel filters having such a configuration are arranged and housed between metal plates (cases). In the figure, IN2, IN4, IN6 and IN8 are input connectors respectively, and 12, 14, 16 and 18 are isolators for supplying signals from each input connector to the coupling loop of each resonator (channel filter). JUb is a junction unit that combines the outputs of the resonators F2, F4, F10 and F12 shown in FIG. JUd
Is a junction unit that combines the outputs of the resonators F6, F8, F14 and F16 shown in FIG.

By configuring as above, each input connector IN
The signals input from the odd-numbered signal input connectors 1 to IN31 are power-combined by the four junction units and coaxial cables, etc., and then supplied to the circulator C1, and input from the even-numbered signal input connectors IN2 to IN32. The signals thus combined are power-combined by four junction units and a coaxial cable and supplied to the circulator C2. Circulators C1 and C2
Half of the input power of the dummy loads R2 and R1 respectively
Is absorbed by and the combined signal is output from the output terminal OUT.

Further, the air-cooling fans 60 to 67 directly cool the cavities of the 32 dielectric resonators to suppress the temperature rise of the dielectric resonators. Especially, the air cooling fans 63 and 64 suppress the heat generation of the dummy loads R1 and R2. Since each dielectric resonator is in TM mode, and the internal dielectric is in direct contact (molded together) between the two faces of the cavity, the heat of the internal dielectric is efficiently radiated from the surface through the cavity. Is
The temperature rise of the internal dielectric is small. Therefore, the frequency fluctuation is stabilized and the insertion loss is reduced.

In the first and second embodiments, single-mode dielectric resonators are used as the channel filters, but one multi-TM mode dielectric resonator is used as a multi-stage channel filter or for multiple channels. It may be used as a channel filter.

(H) Effect of the Invention According to the present invention, by using the TM mode dielectric resonator as the channel filter, it is possible to make the device compact while having a relatively high Q. By integrating the junction unit provided with and the signal output coupler with the channel filter unit, the overall size can be further reduced. Further, since each channel filter is a TM mode dielectric resonator, the heat dissipation efficiency is high and the temperature rise is suppressed. Therefore, the frequency fluctuation is small and the insertion loss can be suppressed low. As described above, the transmission resonator having the reduced size, the reduced loss, and the reduced cost can be used for the base station of the cellular system with the reduced cell radius.

[Brief description of drawings]

1 to 6 are views showing the configuration of a transmission common device according to a first embodiment of the present invention, and FIG. 1 is a perspective view when a channel filter unit and a junction unit are separated, and FIG. The figure is a perspective view when both are assembled. FIG. 3 and FIG. 4 are an exploded perspective view and a sectional view showing the structure of a dielectric resonator that constitutes one channel filter. 5 and 6 are a schematic plan view and a partial sectional view showing the configuration of the junction unit. 7 to 9 are diagrams showing the configuration of the transmission sharing apparatus according to the second embodiment of the present invention, and FIGS. 7 (A) and 7 (B) are external perspective views, FIG. 8 and FIG. FIG. 9 is a schematic plan view and a schematic sectional view. 1 ... Case, 15, 16 ... Ceramic substrate, 17 ... Coupling probe (signal output coupler), 18 ... Central conductor, 45 ... Electrode (transmission line) (branch line), 50 ... Ceramic body , 51 …… Internal dielectric, 53,55 …… Ceramic plate, 100 …… Channel filter unit, 101, JUa to JU
h ... junction unit, IN ... signal input connector, OUT ... signal output connector, I ... isolator,
F: Dielectric resonator (channel filter).

Continuation of the front page (56) References JP-A-63-263802 (JP, A) JP-A-61-136302 (JP, A) Actually-opened Shou 64-30902 (JP, U)

Claims (1)

[Claims] 1. A plurality of TM mode dielectric resonators, each of which has an insertion hole for a signal input coupler and an insertion hole for a signal output coupler, and which passes a band of a specific channel, at least for the signal output coupler. A channel filter unit having the insertion holes arranged on the same surface and two substrates are stacked, a transmission electrode is provided inside the substrate, and a signal output coupler is projected from the transmission electrode to the outside of the substrate. The transmission electrode constitutes a branch line for synthesizing the signal of the signal output coupler, and a junction unit in which a conductor of the output section is connected to the synthesizing point, and the signal output coupler insertion hole of the channel filter unit. Insert the connector for signal output of the above junction unit to connect the junction unit to the channel filter unit. And a shared transmission device.