JPH08275230A - Frequency allocation system in mobile communication system - Google Patents

Abstract

PURPOSE: To realize excellent two-way communication processing with a high frequency utilization efficiency without complicated configuration of a transmission reception circuit when the information amount in an outgoing way from a base station to a terminal equipment is considerably more than an incoming information amount from the terminal equipment to the base station. CONSTITUTION: A difference Δf of center frequencies between an incoming channel with a narrow band and an outgoing channel with a broad band among plural channels CH1 , CH2 ,..., is set to a prescribed value and the channels are allocated to a lower pass band 1 and an upper pass band 2 of a terminal duplexer. The incoming channel and the outgoing channel are arranged among the adjacent channels CH1 , CH2 ,... by alternately replacing the incoming and outgoing channels. Otherwise, an odd channel group 1 (CH1 , CH3 ,...) where the incoming channels are allocated to the lower band and the outgoing channels are allocated to the upper band and an even channel group 2 (CH2 , CH4 ,...) where the incoming channels are allocated to the upper band 2 and the lower channels are allocated to the lower band 1 are grouped and allocated to a terminal equipment.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frequency used in a mobile communication system for bidirectional wireless communication between a central base station and a plurality of mobile terminals in an office or a station. Regarding arrangement method.

[0002]

2. Description of the Related Art In a bidirectional mobile communication system using FDD (Frequency Division Duplex), the communication band of a downlink communication channel from a base station to a terminal and the communication of an uplink communication channel from a terminal to a base station. Bands are divided, and a duplexer is provided in a transceiver unit of a base station or a terminal to separate an upstream signal and a downstream signal.

FIG. 10 is a diagram showing a configuration of conventional frequency allocation in a mobile communication system. That is, when five communication channels can be selected in the mobile communication system, the upstream channels CH1 to CH5 and the downstream channels CH1 to CH5 are arranged at constant frequency intervals, and the upstream channels CH1 to CH5 are arranged on the lower side. In the band,
By dividing the downlink channels CH1 to CH5 into the upper band, the frequency difference Δf between the corresponding uplink and downlink channels.
Are set to be constant.

FIG. 11 is a block diagram showing a structure of a transmission / reception circuit of a mobile terminal in a mobile communication system. FIG.
FIG. 2 is a diagram showing frequency attenuation characteristics in the duplexer of the mobile terminal.

For example, when a downlink signal (CH1) transmitted from a base station (not shown) is received via the antenna AT of the mobile terminal, the downlink channel CH1 is band-limited in the downlink pass band of the duplexer 1001. The signal is taken out to the receiving terminal 1002 and amplified by the low noise amplifier 1004.

The signal of the downlink channel CH1 amplified by the low noise amplifier 1004 is mixed by the mixer 1006.
And is down-converted to an intermediate frequency by an oscillation signal of a predetermined frequency f0 generated by the synthesizer 1008.

The down signal down-converted to the intermediate frequency by the predetermined frequency f 0 is filtered through the band pass filter F and supplied to the mixer, and the upper and lower channel frequency difference Δf generated by the oscillator 1009.
The oscillation signal f1 corresponding to (= f1 -f2) is down-converted to the base band.

Further, after being band-limited by the band-pass filter 1011, it is detected and received via the wave detector 1013. On the other hand, the upstream baseband signal output from the modulator 1012 is supplied to the mixer, and the oscillator 101
Upper and lower channel frequency difference Δf (= f1
It is up-converted to an intermediate frequency by the oscillation signal f2 according to -f2).

The upstream signal up-converted to the intermediate frequency is further supplied to the mixer 1007 and up-converted to the signal of the upstream channel CH1 by the oscillation signal of the predetermined frequency f0 generated by the synthesizer 1008.

Then, the upstream channel CH1 is amplified by the power amplifier 1005 and then transmitted to the transmission terminal 100.
3 is supplied to the duplexer 1001, is band-limited in its upstream pass band, is separated from the downlink channel CH1, and is transmitted from the antenna AT to the base station.

That is, by arranging the frequency of the upstream channel and the frequency of the downstream channel in the upper and lower portions and transmitting and receiving the signal with the band limited by the duplexer 1001, bidirectional communication can be realized, and the upper and lower channels can be realized. By arranging a constant frequency difference Δf of the above, the synthesizer 1008 for performing the up-conversion from the intermediate frequency to the up channel and the down conversion from the down channel to the intermediate frequency requires only one unit with its oscillation frequency being constant at f0, Moreover, the oscillation frequencies f of the oscillators 1009 and 1010 for performing conversion to the baseband
1 and f2 can also be set to fixed values.

In the conventional mobile communication system, both the upstream signal and the downstream signal, such as mobile telephone communication, are mainly signals for transmitting voice information.
The occupied frequency bandwidth of the uplink channel and the occupied frequency bandwidth of the downlink channel are both the same bandwidth.

[0013]

However, in future mobile communication systems, a database search and various data edits are performed on the base station side in response to a request given as an upstream signal from a terminal, and a response transmission is made as a downstream signal. It is considered that the communication system in which the information amount of the downlink signal received by the terminal transmitted by the base station and received by the terminal becomes larger than the amount of information of the uplink signal received by the terminal and received by the terminal becomes mainstream. It is very wasteful in terms of frequency utilization efficiency to make the occupied frequency bandwidth of the uplink channel the same as the occupied frequency bandwidth of the downlink channel as in the frequency arrangement configuration (see FIG. 10) in the conventional mobile communication system. There is a problem.

The present invention has been made in view of the above problems, and when the amount of information on the downlink from the base station to the terminal is significantly larger than the amount of information on the uplink from the terminal to the base station, the transmission / reception circuit It is an object of the present invention to provide a frequency allocation method in a mobile communication system with high frequency utilization efficiency, which enables good bidirectional communication processing without requiring a complicated configuration.

[0015]

That is, a frequency allocation method in a mobile communication system according to claim 1 of the present invention is such that bidirectional communication is performed between a base station and a plurality of terminals via a frequency-divided wireless line, In the mobile communication system in which the communication band of the downlink wireless line from the base station to the terminal is set wider than the communication band of the uplink wireless line to the base station, it is used in the uplink wireless line and the downlink wireless line. The uplink channel and the downlink channel in each of the plurality of radio channels are arranged with the frequency difference set to be constant, and the uplink channel and the downlink channel are alternately arranged between adjacent radio channels. Is characterized by.

According to a second aspect of the present invention, there is provided a frequency allocation system in a mobile communication system, in which a base station and a plurality of terminals communicate bidirectionally via a frequency-divided wireless line, and the base station transfers to the terminals. In the mobile communication system in which the communication band of the downlink wireless line of the terminal is set wider than the communication band of the uplink wireless line to the base station, each of the plurality of wireless channels used in the uplink wireless line and the downlink wireless line In addition to arranging the uplink channel and the downlink channel in which the frequency difference is set to be constant, the uplink channel and the downlink channel are alternately arranged between adjacent radio channels, and the frequency of the downlink channel is A group of radio channels higher than the frequency of the channel and a group of radio channels whose uplink channel frequency is higher than the frequency of the downlink channel. Poppy, wherein the assigned to each radio channel group the different terminals.

[0017]

That is, in the frequency allocation method in the mobile communication system according to the first aspect, in the lower pass band of the terminal duplexer, the narrow band upstream of the odd-numbered or even-numbered channel of the plurality of adjacent radio channels is used. Channels and even wideband downlink channels of even-numbered or odd-numbered channels are alternately arranged adjacent to each other, and the wideband downlink channel of the odd-numbered or even-numbered channel and the even-numbered or odd-numbered channel are arranged in the upper passband of the same duplexer. The narrowband upstream channel of the No. channel is alternately arranged adjacently, and
Since the center frequency difference between the upper and lower channels is set to be constant, bidirectional communication using the duplexer can be realized with high frequency utilization efficiency, and up conversion from the intermediate frequency to the up channel and from the down channel to the intermediate channel. A synthesizer for down-converting to a frequency can be shared by one unit with its oscillation frequency fixed, and the oscillation frequencies of the two oscillators for performing conversion with the upper and lower basebands are also set to fixed values. You can do it.

Further, in the frequency allocation method in the mobile communication system according to claim 2, in the frequency allocation method according to claim 1, the uplink channel is allocated in the lower band and the downlink channel is allocated in the upper band. Grouped into one of an odd-numbered or even-numbered channel group and an even-numbered or odd-numbered other channel group in which the upstream channel is arranged in the upper band and the downstream channel is arranged in the lower band. Among the terminals, the terminal to which the one channel group is assigned and the terminal to which the other channel group is assigned can be divided, so that the terminal having the conventional configuration can be used as it is.

[0019]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a conceptual diagram showing the overall configuration of a mobile communication system having a plurality of communication areas A1 and A2.

In the communication area A1 corresponding to the base station (BS) 121, a plurality of mobile terminals (terminals) are provided.
11a1, 11b1, ... Are provided. Similarly, in the communication area A2 corresponding to the base station (BS) 122, a plurality of mobile terminals 11a2 and 11b2 are provided.
, ... are provided.

For example, in the communication area A1, when an uplink signal such as a data search request is transmitted from the mobile terminals 11a1, 11b1, ... And received by the base station 121, the base station 121 responds to the terminal request. The control system (CS) 14 is activated via the network 13 and the necessary information is fetched from the databases 15a, 15b, ....

The information taken in by the base station 121 is used as a downlink signal, and the requested mobile terminal 11a1, 1a1
1b1, ... Is transmitted. Here, each mobile terminal 1
The uplink signals transmitted from 1a1, 11b1, ... To the base station 121 are control information such as channel selection and media selection, or voice information.
The downlink signals transmitted from the mobile terminals 11a1, 11b1, ... To the mobile terminals 11a1, 11b1, ... Are images of selected channels, audio information, file editing information of selected media, and the like.

That is, the mobile terminals 11a1, 11b1,
The amount of information of the upstream signal from ... Is very small, and the amount of information of the downstream signal from the base station 121 is very large. Therefore, the signal of the upstream channel from each terminal 11a1, 11b1 ,. It is used to transmit at low speed, and the downlink channel signal from the base station 121 is transmitted at high speed using a wide band.

FIG. 2 shows a first example of the mobile communication system.
It is a figure which shows the structure of the frequency arrangement of FIG. That is, the center frequencies of the uplink channels CH1 to CH5 and the downlink channel C
Each of the center frequencies of H1 to CH5 is arranged at a constant frequency interval, and the upstream channels CH1 to CH5 are arranged.
Is set to the lower band, the downlink channels CH1 to CH5 are divided to the upper band, and the frequency difference Δf between the corresponding channels of the uplink and the downlink is set to be constant.

Since the amount of information transmitted using the uplink channels CH1 to CH5 is small, the occupied bandwidth of each of them is set to a narrow band, and the downlink channel CH1 is set.
Since a large amount of information is transmitted using CH5, the occupied bandwidth of each of them is set to a wide band.

In the configuration of the first frequency arrangement shown in FIG. 2, the frequency of the upstream channel and the frequency of the downstream channel are vertically divided and arranged, and the frequency difference Δf between the upper and lower channels is arranged to be constant. Therefore, the conventional mobile terminal (see FIG. 11) can be used as it is, and the bandwidth of the uplink channel can be narrowed in accordance with the difference in the amount of transmission information between the uplink signal and the downlink signal. Since the bandwidth of the downlink channel is set and the bandwidth of the downlink channel is set to a wide band, the frequency utilization efficiency can be improved.

However, in the configuration of the first frequency arrangement, although the bandwidths of the upstream channel and the downstream channel are made different in magnitude depending on the difference in the amount of transmitted information, the frequency utilization efficiency can be improved to some extent. On the other hand, since the unused band is widened among the uplink channels CH1 to CH5 whose bandwidth is narrow, there is a problem that the frequency utilization efficiency is not good.

FIG. 3 shows a second part of the mobile communication system.
It is a figure which shows the structure of the frequency arrangement of FIG. That is, in the configuration of the first frequency arrangement in which the bandwidths of the uplink channels CH1 to CH5 are narrow bands and the bandwidths of the downlink channels CH1 to CH5 are wide bands, the uplink channels CH1 to CH5 are narrow bands. Are arranged adjacent to each other.

With the configuration of the second frequency arrangement shown in FIG. 3, there is almost no unused band between the upstream channels CH1 to CH5 as compared with the configuration of the first frequency arrangement. Therefore, although the frequency utilization efficiency is very good, the frequency difference Δf between the upper and lower channels is Δf1 <... <in each of the channels CH1 to CH5.
Since it is not constant with Δf5, it is not possible for a mobile terminal to share a synthesizer for up-converting from the intermediate frequency to the up channel and down-converting from the down channel to the intermediate frequency by one unit, which is dedicated to the up conversion. There is a problem that two synthesizers are required, a synthesizer for generating the frequency fu and a synthesizer for generating the frequency fd exclusively for the down conversion.

FIG. 4 shows a third example of the mobile communication system.
It is a figure which shows the structure of the frequency arrangement of FIG. That is, the uplink channel set to the narrow band and the downlink channel set to the wide band are arranged alternately adjacent to each of the channels CH1 to CH5.

With the configuration of the third frequency arrangement shown in FIG. 4, the frequency utilization efficiency is good, and the frequency difference Δf between the upstream channel and the downstream channel is constant in both channels, so that in the mobile terminal, Although a single synthesizer can be used for up-conversion from the intermediate frequency to the up channel and down conversion from the down channel to the intermediate frequency, the frequency bands of the up channel and the down channel can be changed to upper and lower frequency bands. Since the separate arrangement can be performed only for each channel, all the upper and lower channels in the plurality of channels CH1 to CH5 cannot be separated by the duplexer having the same frequency attenuation characteristic.

For this reason, there is a problem that the duplexer cannot be used to perform bidirectional communication using a plurality of channels selectively. FIG. 5 is a diagram showing the configuration of the fourth frequency arrangement in the mobile communication system and the frequency attenuation characteristics of the duplexer in the mobile terminal in comparison, and FIG. 5A shows the frequency arrangement diagram and FIG. ) Is a frequency attenuation characteristic diagram thereof.

That is, a plurality of channels CH1, CH
The narrow band upstream channel and the wide band downstream channel in each of 2, ... Are set to have a constant center frequency difference Δf between the upper and lower channels, and the lower pass band 1 and the upper pass band of the duplexer are set. The band 2 is arranged separately, and the uplink channel and the downlink channel are arranged alternately between the adjacent channels CH1, CH2 ,.

That is, the lower pass band 1 of the duplexer
In the frequency band corresponding to, the odd-numbered narrowband upstream channels CH1, CH3, ... And the even-numbered wideband downlink channels CH2, CH4 ,. In the frequency band corresponding to
H1, CH3, ... And narrow band upstream channels CH2, CH4, ... Of even channels are alternately arranged adjacent to each other, and the center frequency difference Δf between the upper and lower channels is set to be constant.

Here, the transmission rate of each narrow band upstream channel is a low rate of several hundred kbps to several kbps, and the transmission rate of each wide band downlink channel is several hundred tens to several Mbps. It's fast.

FIG. 6 shows a fourth example of the mobile communication system.
FIG. 3 is a block diagram showing a configuration of a transmission / reception circuit of a mobile terminal when the frequency arrangement configuration of FIG. Here, the upstream channels CH1, CH3, ... Are in the lower pass band, and the downstream channel C is
When an odd-numbered channel in which H1, CH3, ... Are set to the upper pass band is selected, the transmission output of the transmission power amplifier 104 is output by the duplexer 10 by the switch SW1.
The lower band pass terminal 102 of 0 and the upper band pass terminal 101 of the duplexer 100 are connected to the receiving input of the low noise amplifier 103.

At the same time, an oscillator (2) 112 for outputting an oscillation signal f2 for converting the base band and the lower intermediate frequency band by the switch SW2.
Is connected to a transmission up-conversion mixer (2) 110, and an oscillator (1) 111 that outputs an oscillation signal f1 for converting a base band and an upper intermediate frequency band is a reception down-conversion mixer (1). 1
09 is connected.

On the other hand, when an even channel in which the upstream channels CH2, CH4, ... Are set to the upper pass band and the downstream channels CH2, CH4, ... are set to the lower pass band, the switch SW1 is used for transmission. Power amplifier 104
Of the duplexer 100 is connected to the upper band pass terminal 101 of the duplexer 100, and the lower band pass terminal 102 of the duplexer 100 is connected to the receive input of the low noise amplifier 103.

At the same time, an oscillator (2) 112 for outputting an oscillation signal f2 for converting the base band and the lower intermediate frequency band by the switch SW2.
Is connected to the receiving down-conversion mixer (1) 109, and the oscillator (1) 111 that outputs the oscillation signal f1 for converting the base band and the upper intermediate frequency band is the transmitting up-converting mixer (2). 1
Connected to 10.

That is, when the downlink channel CH1 (odd channel) transmitted from the base station 121 is received via the antenna AT of the mobile terminal 11a1 in the fourth frequency arrangement, the downlink channel CH1 is received.
1 is band-limited in the upper pass band of the duplexer 100 and is taken out to the upper band pass terminal 101.
1 is supplied to the low noise amplifier 103 and amplified.

The signal of the downlink channel CH1 amplified by the low noise amplifier 103 is mixed by the mixer (3) 10
5 and down-converted to an intermediate frequency by an oscillation signal of a predetermined frequency f0 generated by the synthesizer 107.

The downlink signal down-converted to the intermediate frequency by the predetermined frequency f0 is the band-pass filter 10
The signal is filtered through 8 and supplied to the receiving down-conversion mixer (1) 109, and the oscillator (1) 1
Upper and lower channel frequency difference Δf (= f
The oscillation signal f1 corresponding to 1-f2) is down-converted to the base band.

Then, after being band-limited by the band filter 113, the wave is detected and received via the wave detector 115. On the other hand, the upstream baseband signal output from the modulator 114 is supplied to the transmission up-conversion mixer (2) 110, and the up-and-down channel frequency difference Δf (= f1 −f2) generated by the oscillator (2) 112 is obtained. The corresponding oscillation signal f2 is up-converted to an intermediate frequency.

The upstream signal up-converted to the intermediate frequency is further supplied to the mixer (4) 106, and the predetermined frequency f0 generated by the synthesizer 107.
Is oscillated to be up-converted to the signal of the up channel CH1.

Then, the upstream channel CH1 is amplified by the power amplifier 104, and then the lower band pass terminal 102 of the duplexer 100 is passed through the switch SW1.
Is transmitted to the base station 12 1 from the antenna AT by being band-limited to the lower pass band and separated from the downlink channel CH1.

In the fourth frequency arrangement configuration, for example, the downlink channel C transmitted from the base station 121 is transmitted.
When H2 (even channel) is received via the antenna AT of the mobile terminal 11a1, the downlink channel CH2 is band-limited to the lower pass band of the duplexer 100 and taken out to the lower band pass terminal 102, and the switch SW1 Is supplied to and amplified by the low noise amplifier 103.

The signal of the downlink channel CH2, which has been signal-amplified through the low noise amplifier 103, is the mixer (3) 10
5 and down-converted to an intermediate frequency by an oscillation signal of a predetermined frequency f0 generated by the synthesizer 107.

The downstream signal down-converted to the intermediate frequency by the predetermined frequency f0 is the band-pass filter 10
The signal is filtered through 8 and supplied to the receiving down-conversion mixer (1) 109, and the oscillator (2) 1
Upper and lower channel frequency difference Δf (= f
It is down-converted to the base band by the oscillation signal f2 corresponding to 1-f2).

Further, after being band-limited by the band filter 113, the wave is detected and received via the wave detector 115. On the other hand, the upstream baseband signal output from the modulator 114 is supplied to the transmission up-conversion mixer (2) 110, and the upper and lower channel frequency difference Δf (= f1 -f2) generated by the oscillator (1) 111 is generated. The corresponding oscillating signal f1 is up-converted to an intermediate frequency.

The upstream signal up-converted to this intermediate frequency is further supplied to the mixer (4) 106, and the predetermined frequency f0 generated by the synthesizer 107.
Is oscillated to be up-converted to the signal of the up channel CH2.

Then, this upstream channel CH2 is amplified by the power amplifier 104, and then, through the switch SW1, the upper band pass terminal 101 of the duplexer 100.
Is supplied to the base station 121 and is separated from the downlink channel CH2 by being band-limited to the upper pass band.

Therefore, according to the fourth frequency allocation method in the mobile communication system, a plurality of channels CH
, CH2, ..., In the narrow band upstream channel and the wide band downstream channel, the center frequency difference Δf between the upper and lower channels is set to be constant, and the lower pass band 1 of the duplexer 100 is The channels CH1 and C are arranged separately from the upper pass band 2 and are adjacent to each other.
Since the upstream channels and the downstream channels are alternately arranged between H2, ..., In the frequency band corresponding to the lower pass band 1 of the duplexer 100, odd-numbered narrow band upstream channels CH1, CH3 ,. Wide-band downlink channels CH2, CH4, ... Of even channels are alternately arranged adjacent to each other, and wide-band downlink channels CH1, CH3, ... Of odd channels are arranged in the frequency band corresponding to the upper pass band 2 of the duplexer 100. Narrow band upstream channels CH2, CH4, ... Of even channels are alternately arranged adjacent to each other, and the center frequency difference Δf between the upper and lower channels is set to be constant.

Therefore, since the narrow-band upstream channel and the wide-band downstream channel can be transmitted and received by the duplexer 100 with band limitation, bidirectional communication can be realized with high frequency utilization efficiency and the frequency difference Δf between the upper and lower channels. Are arranged so that the synthesizer 107 for performing the up-conversion from the intermediate frequency to the upstream channel and the down-conversion from the downstream channel to the intermediate frequency has a single oscillation frequency of f0,
Moreover, the oscillation frequencies f1 and f of the oscillators (1) 111 and (2) 112 for performing the conversion to the baseband are
2 can also be set to a fixed value.

In this case, the mobile terminals 11a1 and 11b1
, 11a2, 11b2, ... For a terminal similar to the conventional one, a switch SW1 for switching between the upper band pass terminal 101 and the lower band pass terminal 102 of the duplexer 100 in accordance with the selection of the odd channel and the even channel. Since it suffices to provide the switch SW2 for switching between the oscillator (1) 111 and the oscillator (2) 112, it is not necessary to change the substantial configuration of the transmission / reception circuit.

Thus, when the amount of downlink information from the base station to the terminal is significantly larger than the amount of uplink information from the terminal to the base station, there is no need to complicate the configuration of the transmission / reception circuit, and good bidirectional communication is possible. It is possible to realize a mobile communication system with high frequency utilization efficiency that enables communication processing.

In the embodiment, as shown in the configuration of the fourth frequency arrangement in FIG. 5, the narrow band upstream channel and the wide band downstream channel in each of the plurality of channels CH1, CH2 ,. , The center frequency difference Δf between the upper and lower channels is set to be constant, and the lower pass band 1 and the upper pass band 2 of the duplexer 100 are separately arranged and adjacent channels CH
By arranging the uplink channel and the downlink channel alternately between 1, CH2, ...
, 11a2, 11b2, ... are provided with switches SW1 and SW2 that perform switching operation according to the selection of an odd channel and an even channel, without changing the substantial configuration of the transmission / reception circuit. It was made possible to perform various bidirectional communication processing with high frequency utilization efficiency.
As shown in, in the configuration of the fourth frequency arrangement,
The odd-numbered channel group 1 (CH1, CH3, ...) And the even-numbered channel group 2 (CH2, CH4, ..
3, ...) and the even channel group 2
If the terminals to which (CH2, CH4, ...) Are assigned are separated, the switches SW1 and SW2 are provided for each terminal.
It is not necessary to provide the terminal, and the terminal having the conventional configuration can be used as it is.

FIG. 7 shows a fourth example of the mobile communication system.
It is a figure which shows the grouping state of the structure of the frequency arrangement of FIG. FIG.
Are in the fourth frequency allocation grouped in the mobile communication system, and the odd channel group 1 (CH1, CH
3, ...) is a diagram showing a configuration of a mobile terminal to which is assigned, FIG. 7A is a block diagram showing a transmission / reception circuit thereof, and FIG. 7B is a diagram showing frequency attenuation characteristics of the duplexer 100. is there.

That is, the odd channel group 1 (CH
1, CH3, ..., Uplink channels (CH1, CH
, ...) are all arranged in the lower frequency band, and all the downlink channels (CH1, CH3, ...) Are arranged in the upper frequency band, so that the upstream channels (CH1, CH3, ...) Output from the power amplifier 104. ,) Are applied to the lower band pass terminal 502 of the duplexer 100 and are band-limited in the lower pass band 1, and are separated from the downstream channels (CH1, CH3, ...).

The downlink channels (CH1, CH3, ...) Received from the antenna AT are band-limited to the upper pass band 2 of the duplexer 100 and taken out to the upper band pass terminal 501.

Then, the downlink channels (CH1, CH3,
The oscillator (1) 5 that outputs the oscillation signal f1 for down-converting the upper intermediate frequency band of
03 is connected to the receiving down-conversion mixer (1) 109, and uses the base band as an upstream channel (CH1,
The oscillator (2) 504 that outputs the oscillation signal f2 for up-converting to the lower intermediate frequency band of CH3, ...) is connected to the transmitting up-converting mixer (2) 110.

FIG. 9 shows a fourth frequency arrangement divided into groups in the mobile communication system.
It is a figure which shows the structure of the mobile terminal to which (CH2, CH4, ...) Is allocated, the same figure (A) is a block diagram which shows the transmission / reception circuit, and the same figure (B) shows the frequency attenuation characteristic of the duplexer 100. FIG.

That is, the even channel group 2 (CH
2, CH4, ..., Uplink channels (CH2, CH
, Are all arranged in the upper frequency band, and all the downlink channels (CH2, CH4, ...) Are arranged in the lower frequency band, so that the upstream channels (CH2, CH4, CH4) output from the power amplifier 104 are all arranged. ..) is given to the upper band pass terminal 802 of the duplexer 100 and band-limited by the upper pass band 2 to separate from the downstream channels (CH2, CH4, ...).

The downlink channels (CH2, CH4, ...) Received from the antenna AT are band-limited to the lower pass band 1 of the duplexer 100 and taken out to the lower band pass terminal 801. .

Then, the downlink channels (CH2, CH4,
Oscillator (1) 8 which outputs an oscillating signal f2 for down-converting the lower intermediate frequency band to the base band.
03 is connected to the receiving down-conversion mixer (1) 109, and the base band is set to the upstream channel (CH2, CH2).
The oscillator (2) 804 which outputs the oscillation signal f1 for up-converting to the upper intermediate frequency band of CH4, ...) is connected to the transmitting up-converting mixer (2) 110.

Therefore, in the configuration of the fourth frequency arrangement in the above-mentioned embodiment, the odd channel group 1 (CH1, CH3, ...) In which the up channel is arranged in the lower band and the down channel is arranged in the upper band. And an even channel group 2 (CH2, CH4, ...) In which the up channel is arranged in the upper band and the down channel is arranged in the lower band, and the odd channel among the plurality of mobile terminals is grouped. If the terminal to which the group 1 (CH1, CH3, ...) Is assigned and the terminal to which the even channel group 2 (CH2, CH4, ...) Is assigned are separated, the terminal having the conventional configuration can be used as it is. it can.

[0066]

As described above, according to the frequency allocation method in the mobile communication system according to claim 1 of the present invention,
The lower pass band of the terminal duplexer includes a narrow band upstream channel of one of the odd or even number of adjacent multiple radio channels and a wide band downlink channel of the other of the even number or the odd number. The adjacent upper and lower passbands of the same duplexer are alternately arranged and have a wideband downlink channel of one of the odd or even numbered channels and a narrowband upstream channel of the other of the even or odd numbered channels. Are alternately arranged adjacent to each other, and the center frequency difference between the upper and lower channels is set to be constant, so that bidirectional communication using the duplexer can be realized with high frequency utilization efficiency and at the intermediate frequency. A synthesizer for up-converting to the up channel and down-converting from the down channel to the intermediate frequency The vibration frequency can be shared by one as constant, moreover, the oscillation frequency of the two oscillators for performing conversion between the upper and lower baseband also to be set to a fixed value respectively.

According to the frequency allocation method in the mobile communication system according to claim 2 of the present invention, in the frequency allocation method according to claim 1, the uplink channel is allocated in the lower band and the downlink channel is allocated. A group of one of an odd-numbered or even-numbered channel group arranged in the upper band and another channel group of an even-numbered or odd-numbered channel in which the upstream channel is arranged in the upper band and the downlink channel is arranged in the lower band. The plurality of terminals are divided into a terminal allocating the one channel group and a terminal allocating the other channel group, so that the terminal having the conventional configuration can be used as it is.

Therefore, according to the present invention, when the amount of downlink information from the base station to the terminal is significantly larger than the amount of uplink information from the terminal to the base station, there is no need to complicate the configuration of the transmission / reception circuit. It is possible to provide a frequency allocation method in a mobile communication system with high frequency utilization efficiency that enables good bidirectional communication processing.

[Brief description of drawings]

FIG. 1 is a conceptual diagram showing an overall configuration of a mobile communication system having a plurality of communication areas according to an embodiment of a frequency allocation system in a mobile communication system of the present invention.

FIG. 2 is a diagram showing a configuration of a first frequency allocation in the mobile communication system.

FIG. 3 is a diagram showing a configuration of a second frequency allocation in the mobile communication system.

FIG. 4 is a diagram showing a configuration of a third frequency allocation in the mobile communication system.

FIG. 5 is a diagram showing a configuration of a fourth frequency arrangement in the mobile communication system and a frequency attenuation characteristic of a duplexer in a mobile terminal in comparison, and FIG. 5A shows the frequency arrangement diagram and FIG. B) is the frequency attenuation characteristic diagram.

FIG. 6 is a block diagram showing a configuration of a transmission / reception circuit of a mobile terminal when a fourth frequency allocation configuration is used in the mobile communication system.

FIG. 7 is a diagram showing a grouping state of a fourth frequency arrangement configuration in the mobile communication system.

FIG. 8 is a diagram showing a configuration of a mobile terminal to which an odd-numbered channel group 1 is assigned in the fourth frequency allocation grouped in the mobile communication system, and FIG. FIG. 2B is a block diagram showing the frequency attenuation characteristic of the duplexer.

FIG. 9 is a diagram showing a configuration of a mobile terminal to which the even channel group 2 is assigned in the fourth frequency allocation grouped in the mobile communication system, and FIG. FIG. 2B is a block diagram showing the frequency attenuation characteristic of the duplexer.

FIG. 10 is a diagram showing a configuration of frequency allocation in a conventional mobile communication system.

FIG. 11 is a block diagram showing a configuration of a transmission / reception circuit of a mobile terminal in the conventional mobile communication system.

FIG. 12 is a diagram showing frequency attenuation characteristics in the duplexer of the conventional mobile terminal.

[Explanation of symbols]

A1, A2 ... communication area, 11a1, 11b1, 11c
1, 11a2, 11b2, 11c2 ... Mobile terminal, 12
1, 122 2 ... Base station, 13 ... Network, 14 ... Control system, 15a, 15b ... Database, C
H1, CH2, CH3 ... Radio channel, AT ... Antenna, 100 ... Duplexer, 101 ... Upper band pass terminal, 102 ... Lower band pass terminal, 103 ... Low noise amplifier, 104 ... Power amplifier, 105 ... Reception mixer (3) ,
106 ... Transmission mixer (4), 107 ... Synthesizer, 1
08 ... bandpass filter, 109 ... reception down-conversion mixer (1), 110 ... transmission up-conversion mixer (2), 111 ... oscillator (1), 112 ... oscillator (2), 113 ... bandpass filter, 114 ... modulator , 11
5 ... Detector, SW1, SW2 ... Switch.

Claims (2)

[Claims] 1. A base station and a plurality of terminals are bidirectionally communicated via a frequency-divided radio line, and a communication band of a downlink radio line from the base station to the terminal is transmitted from the terminal to the base station. In a mobile communication system that is set wider than the communication band of an upstream wireless line, the frequency difference between the upstream and downstream channels of each of the plurality of wireless channels used in the upstream wireless line and the downstream wireless line is set to be constant. A frequency allocation method in a mobile communication system, wherein the uplink channel and the downlink channel are alternately switched between adjacent radio channels. 2. A base station and a plurality of terminals are bidirectionally communicated via a frequency-divided radio line, and a communication band of a downlink radio line from the base station to the terminal is transmitted from the terminal to the base station. In a mobile communication system that is set wider than the communication band of an upstream wireless line, the frequency difference between the upstream and downstream channels of each of the plurality of wireless channels used in the upstream wireless line and the downstream wireless line is set to be constant. And the uplink channels and downlink channels are alternately switched between adjacent radio channels, and the radio channel group in which the frequency of the downlink channel is higher than the frequency of the uplink channel and the frequency of the uplink channel is the downlink channel. And a radio channel group having a frequency higher than that of each of the above, and each radio channel group is assigned to a different terminal. Frequency allocation scheme in Shin system.