JPH10290176A - Antenna multicoupler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the antenna multicoupler with an excellent characteristic. SOLUTION: A reception band and a transmission band are respectively divided into two channels. Reception filters 11, 12 are provided, which use a frequency band of each channel in the reception band as a pass band. Transmission filters 21, 22 are provided, which use a frequency band of each channel in the transmission band as a pass band. Switch circuits 74-76 are provided, which select the filters 11-22 according to a channel used for the transmission reception. The reception filters 11, 12 are encapsulated into one package 10. The transmission filters 21, 22 are encapsulated into one package 20.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an antenna sharing device.

[0002]

2. Description of the Related Art In an analog type mobile telephone, for example, a portable telephone, it is necessary to simultaneously perform transmission and reception and to share one antenna for transmission and reception in order to realize two-way simultaneous communication. . For this reason, such a mobile phone is provided with an antenna duplexer (duplexer), and this antenna duplexer generally uses a dielectric filter.

However, when an antenna duplexer is formed using a dielectric filter, the shape becomes large. In this regard, if the antenna duplexer is configured using the SAW filter, it is possible to reduce the size more than that using the dielectric filter.

However, for example, CDMA in the 800 MHz band in Japan
In a cellular system, the reception band is 832 MHz.
870 MHz and a transmission band of 887 MHz to 925 MHz, the transmission band and the reception band are wide, and the frequency interval between the transmission band and the reception band is narrow. It is difficult for the SAW filter to satisfy such a band and frequency interval.

Therefore, it has been considered to configure the antenna duplexer as follows. That is, first, as shown in FIG. 3, the reception band fR is divided into a band fR1 and a band fR2, and the transmission band fT is also divided into the band fT1 and the band fR.
Divided into T2.

Then, as shown in FIG. 4, a first antenna duplexer 31 is composed of the filter 11 having a pass band of the band fR1 and the filter 21 having a pass band of the band fT1. A filter 1 having a band fR2 as a pass band.
2 and the filter 22 having the band fT2 as a pass band, form a second antenna duplexer 32.

When a call is made using channels included in the bands fR1 and fT1, switch circuits 74 to 76 are connected in the state shown in FIG. The transmission signal (high-frequency signal) from 50 is supplied to the transmission / reception antenna 60 through the signal line of the switch circuit 75 → the filter 21 → the switch circuit 76, and transmitted from the antenna 60 to the base station. Also, the signal from the base station is transmitted to the antenna 6
0 is received by the switch circuit 76
→ Filter 11 → Supplied to the receiving circuit 40 through the signal line of the switch circuit 74.

Further, when a call is made using the channels included in the bands fR2 and fT2, the system control microcomputer switches the switch circuits 74-7.
6 is connected in a state opposite to that shown in the figure, and a transmission signal from the transmission circuit 50 is supplied to the transmission / reception antenna 60 through a signal line of the switch circuit 75 → the filter 22 → the switch circuit 76, and transmitted to the base station. Further, a reception signal of the antenna 60 is supplied to the reception circuit 40 through a signal line of the switch circuit 76 → the filter 12 → the switch circuit 74.

Therefore, the filters 11 to 22 need not have a narrow pass band and have a wide frequency interval, so that the filters 11 to 22 can be constituted by SAW filters. However, even if the antenna is divided into the duplexers 31 and 32, the size can be reduced more than the antenna duplexer formed by the dielectric filter.

[0010]

However, as shown in FIG. 4, the reception filter 11 and the transmission filter 21 are integrated to form an antenna duplexer 31, or the reception filter 12 and the transmission filter 22 are combined. When the antenna duplexer 32 is configured by integrating the above, the signal interference or leakage generated between the reception filter 11 and the transmission filter 21 or between the reception filter 12 and the transmission filter 22 causes The receiving circuit 40 is easily affected by the transmission signal. That is, the characteristics as the antenna duplexer are deteriorated.

The present invention is intended to solve such a problem.

[0012]

For this reason, according to the present invention, a first frequency band having a predetermined bandwidth is set as a reception band, and a second frequency band having a predetermined width is separated from the first reception band by a predetermined interval. When the reception band and the transmission band are respectively divided into first to Nth channels (N ≧ 2), the frequency band of each channel in the reception band is A first to N-th receiving filters having a pass band; and a first receiving filter having a frequency band of each channel of the transmission band as a pass band.
To a N-th transmission filter, and a switch circuit for selecting the first to N-th reception filters and the first to N-th transmission filters according to channels used for transmission and reception. The first to N-th reception filters are packaged in one package, and the first to N-th transmission filters are packaged in one package. Therefore,
Signal interference and leakage between the reception filter and the transmission filter are reduced.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In FIG.
1 and 12 are packaged in one package 10, and the transmission filters 21 and 22 are packaged in one package 20.
0 forms an antenna duplexer.

In this case, the hatched band in FIG. 2 is the band used in the 800 MHz band CDMA cellular system in Japan. If the apparatus of FIG. 1 is used in this system, the filter 11
The pass bands of 12, 21, and 22 are respectively the band f of FIG.
R1, fR2, fT1, and fT2. Also, the filters 11 to
Reference numeral 22 includes, for example, a SAW filter.

Further, a transmitting / receiving antenna 60 is connected to the input terminals of the receiving filters 11 and 12 through the switch circuit 76 and to the output terminals of the transmitting filters 21 and 22. The output terminals of the reception filters 11 and 12 are connected to the input terminal of the reception circuit 40 through the switch circuit 74, and the output terminal of the transmission circuit 50 is connected to the switch circuit 75.
Are connected to the input terminals of the transmission filters 21 and 22 through the transmission line.

Although not shown, the channels used by the reception circuit 40 and the transmission circuit 50 are controlled by a system control microcomputer.
The switch circuits 74 to 76 are controlled by the microcomputer corresponding to the channels used by the reception circuit 40 and the transmission circuit 50.

In such a configuration, the bands fR1, fT1
When a call is performed using a channel included in the transmission circuit 5, the system control microcomputer connects the switch circuits 74 to 76 in the state shown in FIG.
The transmission signal (high-frequency signal) from the switch circuit 75
The signal is supplied to the transmitting / receiving antenna 60 through the signal line of the filter 21 and the switch circuit 76, and transmitted from the antenna 60 to the base station. A signal from the base station is received by the antenna 60, and the received signal is supplied to the receiving circuit 40 through a signal line of the switch circuit 76 → the filter 11 → the switch circuit 74.

Further, when a call is made using the channels included in the bands fR2 and fT2, the system control microcomputer switches the switch circuits 74 to 7 to each other.
6 is connected in a state opposite to that shown in the figure, and a transmission signal from the transmission circuit 50 is supplied to the transmission / reception antenna 60 through a signal line of the switch circuit 75 → the filter 22 → the switch circuit 76, and transmitted to the base station. Further, a reception signal of the antenna 60 is supplied to the reception circuit 40 through a signal line of the switch circuit 76 → the filter 12 → the switch circuit 74.

Thus, in this antenna duplexer, the reception band fR and the transmission band fT are divided into two, and the pass bands of the filters 11 to 22 are narrowed to 1/2 of the reception band fR and the transmission band fT. The frequency interval is widened. Therefore, the filters 11 to 22 are
As a result, even if the duplexer is divided into the packages 10 and 20, the size can be reduced more than the duplexer formed by the dielectric filter.

In that case, the package 10 includes
Since the receiving filters 11 and 12 are provided and the transmitting filters 21 and 22 are provided in the package 20, the signal between the receiving filters 11 and 12 and the transmitting filters 21 and 22 is Interference and leak can be eliminated, and the receiving circuit 40 is less likely to be affected by the transmission signal. That is, it has excellent characteristics as an antenna duplexer.

In the above description, the reception band fR and the transmission band fT are each divided into three or more bands, and therefore, the packages 10 and 20 are divided into three or more filters each having a pass band as the divided band. It can also be configured. Further, the receiving filters 11 and 12 may be configured by a SAW filter, and the transmitting filters 21 and 22 may be configured by a dielectric filter.

[0022]

According to the present invention, the size can be reduced as compared with an antenna duplexer constituted by a dielectric filter. Moreover, it has excellent characteristics as an antenna duplexer.

[Brief description of the drawings]

FIG. 1 is a system diagram illustrating one embodiment of the present invention.

FIG. 2 is a frequency characteristic diagram for explaining the present invention.

FIG. 3 is a frequency characteristic diagram for explaining the present invention.

FIG. 4 is a system diagram for explaining the present invention.

[Description of Signs] 10 and 20 = Package, 11 and 12 = Receive Filter, 21 and 22 = Transmit Filter, 40 = Receive Circuit, 50 = Transmit Circuit, 60 = Transceive Antenna, 74
-76 = Switch circuit

Claims (2)

[Claims] An antenna sharing apparatus in which a first frequency band having a predetermined bandwidth is set as a reception band and a second frequency band having a predetermined width separated by a predetermined interval from the first reception band is set as a transmission band. , The reception band and the transmission band, respectively,
When divided into channels (N ≧ 2), the first to Nth reception filters each having a pass band for each frequency band of each channel of the reception band, and a pass band for each frequency band of each channel of the transmission band. According to the first to Nth transmission filters to be used, and the channel used for transmission and reception,
A switch circuit for selecting the N-th reception filter and the first to N-th transmission filters; packaging the first to N-th reception filters in one package; An antenna sharing device in which N transmission filters are packaged in one package. 2. The antenna sharing apparatus according to claim 1, wherein said receiving filter or said transmitting filter is an SA.
An antenna sharing device constituted by a W filter.