JP2004215191A - Repeater device for mobile communication - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a repeater device whose reception sensitivity is improved in a dead zone in mobile communication. <P>SOLUTION: A high-frequency signal of a downlink line system from a master set is inputted into the antenna module 6-1 of a slave set via an input output terminal 2, a core wire of a coaxial cable 3-0 and a high-frequency coupler 4-1, and transmitted to a portable terminal from an antenna 10 used for both transmission and reception. A high-frequency signal of an uplink line system to the master set is received by the antenna 10, and is transmitted to the master set side via main lines of a coaxial cable 15-1, the high-frequency coupler 4-1 and a coaxial cable in a state that a noise index is improved by a high-frequency unit consisting of a BPF 8 and a low-noise amplifier 7. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is provided in a mobile communication system including a mobile terminal such as a mobile phone radio (hereinafter, “portable terminal”) and a base station to cover a dead zone of radio waves for signal transmission. Related relay device.
[0002]
[Prior art]
2. Description of the Related Art In recent years, portable terminals for making telephone calls or performing data communication from any place have rapidly become widespread. A communication system that enables communication by a portable terminal includes an exchange connected to a public communication network and a radio base station connected to the exchange. A plurality of wireless base stations are provided for each service area, but since the frequency band used is a high frequency band, when the mobile terminal is in a tunnel, underground shopping mall, or building, radio waves do not reach or hardly reach. ing. Therefore, it is common to provide a relay device in such an area and amplify the radio wave from the wireless base station by the relay device and redistribute it. Such a relay device is connected to a wireless base station through, for example, an optical cable or wireless communication means.
[0003]
FIG. 11 is a configuration diagram of a conventional relay device of this type. This relay device is configured by connecting a master unit 51 and a slave unit 52 in a form capable of two-way communication. An optical cable 33 attached to an input terminal 32 for a downlink (a line from the wireless base station to the mobile terminal, the same applies hereinafter) and an uplink (a line from the mobile terminal to the wireless base station; An example is shown in which the optical fiber cable 35 is connected to an output terminal 34 for the same device) and the coaxial cable 29 connects between the master unit 51 and the slave unit 52.
Master device 51 is configured as shown in FIG. That is, the downstream light intensity modulated signal transmitted by the optical cable 33 and reaching the input terminal 32 is converted into a high-frequency signal by the photoelectric conversion circuit (light-to-electricity: O / E) 30. Then, after the converted high-frequency signal is amplified by the low-distortion amplifier (LPA) 40 of the amplifier module 54, the signal is combined into one communication path together with the uplink communication path by the multiplexer 55, and this is transmitted to the slave unit 52 through the coaxial cable 29. Send out.
[0004]
From the slave unit 52, through the coaxial cable 29, a high-frequency signal of an up-link system (in this specification, a path through which the high-frequency signal of the up-line passes is referred to as “up-link system” for convenience). In this case, a path through which a high-frequency signal of the downlink is passed is referred to as a “downlink system” for convenience) and is input together into one communication path together with a communication path. Master device 51 receives the high-frequency signal, separates only the high-frequency signal transmitted in the uplink system by multiplexer 55, and amplifies the high-frequency signal by low-noise amplifier (LNA) 41 of amplifier module 54. Then, the amplified high-frequency signal is converted into a light intensity modulation signal by a photoelectric conversion circuit (electricity → light: E / O) 31 and transmitted to a wireless base station via an output terminal 34 and an optical cable 35 attached thereto.
[0005]
Note that there is also a wireless system in which a wireless base station and a relay device are wirelessly connected.
FIG. 13 is a configuration diagram of the base unit 61 using a wireless system. Since the master unit 61 transmits and receives both the downlink system high-frequency signal and the uplink system high-frequency signal in the master unit 61, the duplexer 23 is disposed between the antenna connection end 62 and the amplifier module 54. However, for the high-frequency signal of the downlink system, it is separated from the combined communication channel together with the communication channel of the uplink system, and for the high-frequency signal of the uplink system, this is separated together with the communication channel of the downlink system. It is led to the antenna 63 collectively in one communication path. The amplifier module 54 and the multiplexer 55 are the same components as the master unit 51 of the optical cable system.
[0006]
The slave unit 52 is configured to include an antenna module including the antenna 60 and the high-frequency coupler 4, as shown in FIG. The high-frequency coupler 4 is set to a predetermined coupling degree C, and includes an input terminal HI, an output terminal HO, and a branch / coupling terminal 5. The antenna 60 is connected to the branch / coupling terminal 5 via the coaxial cable 15 and the antenna connection end 16.
[0007]
FIG. 15 is a schematic configuration diagram of the child device 52 in FIG. A plurality of slave units 52 having the configuration shown in FIG. 14 are provided in order to be distributed and arranged in a predetermined slave unit service area. That is, the input terminal HI of the high-frequency coupler 4 shown in FIG. 14 and the input / output terminal 2 on the slave unit side are connected by the coaxial cable 3-0 for wiring to form the first-stage high-frequency coupler 4-1. 4-1 and the next-stage high-frequency coupler 4-2, the next-stage high-frequency coupler 4-2 and the third-stage high-frequency coupler,..., 4-n in this order. , 3-2,..., 3- (n-1), and the branching / coupling terminals 5-1 and 5-1 of the high-frequency couplers 4-1 4-2,. 5-2,..., 5-n are provided with wiring coaxial cables 15-1, 15-2,..., 15-n and antenna connection ends 16-1, 16-2,. The antennas 60-1, 60-2, ..., 60-n are connected via -n.
In the figure, C1 is the degree of coupling in the first-stage high-frequency coupler 4-1, C2 is the degree of coupling in the next-stage high-frequency coupler 4-2, and Cn is the degree of coupling in the n-th-stage high-frequency coupler 4-n.
[0008]
The operation of the relay device configured as described above is as follows.
The high-frequency signal of the down-link system transmitted from the master unit 51 in FIG. 11 (or the master unit 61 in FIG. 13) is guided to the input / output terminal 2 on the slave unit side, and further via the coaxial cable 3-0 for wiring. Is input to the first-stage high-frequency coupler 4-1. The combined wave is transmitted from the antenna 60-1 to the portable terminal via the branch / coupling terminal 5-1, the coaxial cable 15-1 and the antenna connection end 16-1. Also, the signals are transmitted from the other antennas 60-2,..., 60-n through the high-frequency couplers 4-2,.
[0009]
On the other hand, an uplink high-frequency signal transmitted from the mobile terminal is received by the antenna 60-1, and guided to the branch / coupling terminal 5-1 via the antenna connection end 16-1 and the coaxial cable 15-1. This high-frequency signal is attenuated by the coupling degree C1 and transmitted through the main line of the high-frequency coupler 4-1. Then, the signal is transmitted from the input / output terminal 2 to the parent device 51 via the coaxial cable 3-0. The same applies to the high-frequency signals received by the other antennas 60-2, ..., 60-n.
[0010]
[Problems to be solved by the invention]
The conventional relay device described above has the following problems.
The first problem is deterioration in the reception sensitivity of the uplink system transmitted from the mobile terminal.
Until the uplink high-frequency signal received by the slave unit's antenna reaches the input terminal (terminal 27 in FIG. 11) of the master unit, the loss of the coaxial cable for wiring between the antenna and the high-frequency coupler and the degree of coupling of the high-frequency coupler In addition, the loss of the coaxial cable for wiring used for cascade-connecting the high-frequency couplers is weighted as noise of the uplink system. Therefore, the S / N (signal-to-noise ratio) of the uplink system is degraded, and depending on the reception status from the mobile terminal, the reception sensitivity at the wireless base station may not satisfy the specified value.
[0011]
The second problem is the sensitivity deterioration of the uplink system corresponding to the modulation method.
Depending on the modulation method, an uplink high-frequency signal from a certain mobile terminal becomes noise with respect to another high-frequency signal for a mobile terminal. Therefore, the control is performed so that the transmission power from the mobile terminal is suppressed to the lowest possible level. At this time, the first problem described above may become an obstacle and control may be disabled.
[0012]
A third problem is a problem of downlink transmission power control.
The loss from the master unit to the slave unit is determined by the line design, but depending on the location of the slave unit, the coaxial cable needs a certain degree of freedom. At this time, if the loss of the coaxial cable is out of the range of the line design, the reception sensitivity of the downlink system deteriorates, the reception sensitivity is suppressed, and the like. Further, in the modulation method as described in the second problem, high-precision transmission power control is required. However, if the length of the coaxial cable for wiring is given a degree of freedom, the transmission power between the slave units is reduced. The deviation increases and control becomes difficult.
[0013]
The present invention is to provide a relay device that can solve the above problem.
[0014]
[Means for Solving the Problems]
A relay device according to a first aspect of the present invention for solving the above-mentioned problems is a device for relaying communication between a mobile terminal and a base station, and includes a master unit and a slave unit connected to the master unit by a coaxial cable. .
The master unit is a wireless communication unit that enables wireless communication with the base station, and a wired communication unit that enables high-frequency signals transmitted and received by the wireless communication unit to be transferred between the slave units via a coaxial cable. Transmission means for transmitting DC power to the slave unit through the coaxial cable,
The slave unit allows wireless communication means having an antenna connection end for connecting an antenna that enables wireless communication with the mobile terminal, and enables the transfer of a high-frequency signal by the coaxial cable between the slave unit and the master unit. It has a wired communication means and a high-frequency unit that enhances the signal characteristics at the antenna connection end as compared with the case without it, and the high-frequency unit can be operated by the DC power transmitted from the master unit.
[0015]
By connecting the master unit and the slave unit with a coaxial cable, it is possible to transmit DC power to the slave unit, which is not possible with an optical cable, so that the slave unit can operate the high-frequency unit without providing a power supply. it can. Therefore, it is extremely easy to add a slave to the master, and the slave can be easily installed in the dead zone. In addition, since the high-frequency unit enhances high-frequency characteristics at the antenna connection end, stable relay of mobile communication can be performed. The “high-frequency characteristics” here include a noise figure of a high-frequency signal, reception sensitivity when receiving a signal from a mobile terminal, a signal waveform, an output level of a high-frequency signal, and the like.
[0016]
A relay device according to a second aspect of the present invention is a device that relays communication between a mobile terminal and a base station, and includes a master unit and a plurality of slave units connected to the master unit by a coaxial cable.
The master unit is a wireless communication unit that enables wireless communication with a base station, and a wired communication unit that enables a high-frequency signal transmitted and received by the wireless communication unit to be transferred between a plurality of slave units via a coaxial cable. Means, and transmission means for transmitting DC power to a plurality of slaves through a coaxial cable,
Each of the plurality of slave units is coupled to the coaxial cable with a predetermined degree of coupling at which the power level for signal transmission is substantially the same as the other slave units,
Each slave unit can transmit and receive a high-frequency signal by a coaxial cable between the master unit and a wireless communication unit having an antenna connection end for connecting an antenna that enables wireless communication with a mobile terminal. And a high-frequency unit that enhances the signal characteristics at the antenna connection end as compared to a case without the wired communication means, and the high-frequency unit can be operated by the DC power transmitted from the master unit.
Since the power level for signal transmission to a plurality of slave units is almost the same, there is no need to adjust the signal level of the high-frequency signal from the master unit according to the circumstances of the slave unit. Control at the time of transmission is easy.
[0017]
A relay device according to a third aspect of the present invention is a device for relaying communication between a mobile terminal and a base station, and includes a master unit and a plurality of slave units connected to the master unit by coaxial cables.
The master unit enables a first wired communication unit that enables optical communication with the base station, and enables a signal transmitted and received by the first wired communication unit to be transferred between a plurality of slave units via a coaxial cable. A second wired communication means, and a transmission means for transmitting DC power to a plurality of slaves through a coaxial cable,
Each of the plurality of slave units is coupled to the coaxial cable with a predetermined degree of coupling at which the power level for signal transmission is substantially the same as the other slave units,
Each slave unit can transmit and receive a high-frequency signal by a coaxial cable between the master unit and a wireless communication unit having an antenna connection end for connecting an antenna that enables wireless communication with a mobile terminal. And a high-frequency unit that enhances the signal characteristics at the antenna connection end as compared to a case without the wired communication means, and the high-frequency unit can be operated by the DC power transmitted from the master unit.
Since signals are transmitted and received between the base station and the master unit by optical communication, stable wired communication can be performed without considering noise.
[0018]
In any one of the first to third inventions, the high-frequency unit included in the slave unit includes, for example, an amplifier that amplifies an uplink high-frequency signal from the mobile terminal to the base station, and removes unnecessary waves of the amplified high-frequency signal. Filters connected in cascade. These components are as follows: if the noise factor of the amplifier is Fa, the gain of the amplifier is G, the noise factor of the filter is Ff, and the noise factor of the uplink system from the connection end of the antenna when no high-frequency unit is present is Fo, The noise factor F of the uplink system as viewed from the connection end of the antenna when the high-frequency unit is provided is set to have the following relationship.
F = Ff · (Fa + (2 · Fo−1) / G)
By providing the components having such a relationship, the noise figure at the time of receiving a high-frequency signal is improved, and the problem of reception sensitivity deterioration at the time of reception from a mobile terminal is solved.
[0019]
In any one of the first to third inventions, the high-frequency unit included in each of the slave units includes, for example, a variable gain amplifier that can adjust the signal level of a high-frequency signal of a downlink system from the base station to the mobile terminal. Be composed. This amplifier is preferably a gain self-control type amplifier that autonomously controls its own gain in accordance with the signal level output from itself. It also has a function of limiting the transmission power of the downlink to a predetermined value or less. This facilitates control during signal transmission when a plurality of slave units are deployed.
[0020]
In the first or second invention, the wireless communication means of the master unit includes, for example, a plurality of transmission / reception units for transmitting / receiving high-frequency signals of different frequencies to / from a base station, The wired communication means included in the device integrates a downstream high-frequency signal output from each of the plurality of transmission / reception units and an upstream high-frequency signal input to each of the plurality of transmission / reception units into one type of signal and coaxially cooperates. It is configured to lead to a cable.
In the third invention, the first wired communication means of the master unit includes a plurality of transmission / reception units for transmitting / receiving high-frequency signals having different frequencies to / from the base station, and the master unit has The second wired communication unit integrates the down-stream high-frequency signal output from each of the plurality of transmission / reception units and the up-stream high-frequency signal input to each of the plurality of transmission / reception units into one type of signal, and forms the coaxial signal. It is configured to lead to a cable. More specifically, the first wired communication unit is configured to include a photoelectric conversion circuit that enables communication with the base station using an optical cable.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment in which the present invention is applied to a relay device configured of a master unit and a plurality of slave units and relaying communication between a mobile terminal as an example of a mobile terminal and its wireless base station will be described. explain.
<First embodiment>
FIG. 1 is a configuration diagram of a master unit according to the first embodiment of the present invention. Here, an example of a case of connecting to a wireless base station by a wireless method will be described. The same components as those of the conventional master unit 61 shown in FIG. 13 are denoted by the same reference numerals.
The master unit 21 of this embodiment includes an antenna connection end 62 for connecting an antenna 63 that can be shared by the downlink system and the uplink system, a power terminal 26 to which a power supply device (not shown) is connected, and a slave device. A connection end 27 for connecting the input / output terminal 2 on the side with a coaxial cable 29 is provided.
[0022]
The high-frequency signal received from the radio base station received by the antenna 63 is separated into a high-frequency signal (hereinafter, referred to as a “first signal”) to be transmitted in the down-link system by the duplexer 23, and then the low distortion of the amplifier module 24 is reduced. The signal is amplified by an amplifier (LPA) 40. The amplified first signal is combined into one communication path together with the communication path of the up-link system by the multiplexer 25, and transmitted to the slave unit via the coaxial cable 29 connected to the connection end 27.
On the other hand, an uplink high-frequency signal (hereinafter, referred to as a “second signal”) from the slave unit group input from the connection end 27 via the coaxial cable 29 is separated by the multiplexer 25 to become a second signal, and the amplifier module After being amplified by 24 low noise amplifiers (LNA) 41, the signal is combined with the first signal by the duplexer 23 into one communication path, and transmitted from the antenna 63 to the wireless base station via the antenna connection end 62.
[0023]
As described above, the multiplexer 25 integrates the downlink communication path into the uplink communication path, thereby transmitting the first signal to the slave unit or from the communication path connected to the slave unit to the uplink line. It operates to separate the communication path and thereby output the second signal to the amplifier module 24.
FIG. 2 is a detailed configuration diagram of the multiplexer 25. The first signal transmitted through the downlink system is amplified by the LPA 40 of the amplifier module 24, and the DC blocking capacitor 25-3 and the downlink filter 25- 1 and is output to the connection end 27. The second signal transmitted through the uplink is input from the slave unit through the connection terminal 27, passes through the uplink filter 25-2 and the DC blocking capacitor 25-4, and is input to the LNA 41 of the amplifier module 24. You.
A low-pass filter for a DC power supply composed of a coil 25-5 and a capacitor 25-6 is connected to a multiplexer common end (= connection end 27) for combining / separating the first signal and the second signal. The DC power supplied from the power supply terminal 26 is supplied through this low-pass filter, and is superimposed on a high-frequency signal such as a first signal and a second signal. The technique of superimposing the high-frequency signal and the DC power is known per se, and a detailed description thereof will be omitted.
[0024]
FIG. 3 shows an example of the configuration of the slave unit that performs bidirectional communication with the master unit 21 configured as described above.
In the slave unit 1A, the input / output terminal 2 (shown on the right side in FIG. 1), the coaxial cable for wiring 3-0, 3-1, 3-2, 3- (n-1) and the high-frequency coupler 4-1 , 4-2,..., 4-n, the antenna modules 6-1, 6-2,.
Each of the antenna modules 6-1, 6-2,..., 6-n has a branching / coupling terminal 5-1, 5-2, 5-n and a coaxial cable 15-1, 15-2,. .., 15-n, the high-frequency signal passes through the core wires of the wiring coaxial cables 15-1, 15-2,..., 15-n, and the DC power passes through the coaxial cable 29 and the wiring. , 6-n through the central conductors of the coaxial cables 15-1, 15-2, ..., 15-n, respectively.
[0025]
The first signal from the master unit 21 is input to the input / output terminal 2 of the slave unit 1A, and is input to the high-frequency coupler 4-1 via the wiring coaxial cable 3-0. The high-frequency coupler 4-1 guides the first signal to the branch / coupling terminal 5-1. .., 4-n via the coaxial cables 3-1 and 3- (n-1).
[0026]
The first signal input to the antenna module 6-1 via the coaxial cable for wiring 15-1 and the antenna connection end 16-1 is guided to the first path for the downlink in the lower part of FIG. After being filtered by the BPF 9, the signal is transmitted from the antenna 10 shared by the downlink and the uplink to the portable terminal.
On the other hand, the second signal transmitted from the mobile terminal and received by the antenna 10 is filtered by the BPF 8 and then amplified by the low noise amplifier 7 to be distributed / integrated 13, the antenna connection 16-1, and the coaxial wiring. The signal is input to the branch / coupling terminal 5-1 via the cable 15-1. In this way, the first signal and the second signal are transferred between the master unit 21 and the slave unit 1A via the coaxial cables 29, 3-0, 15-1.
The same operation is performed for the other antenna modules 6-2,..., 6-n.
[0027]
The low-noise amplifiers 7 of the antenna modules 6-1, 6-2,..., 6-n of the slave unit 1A shown in FIG. (Field effect transistor) or an active element such as a bipolar transistor. The power supply that enables these active elements is obtained by the DC power superimposed on the high-frequency signal in the multiplexer 25.
[0028]
As shown in FIG. 3, when a plurality of slave units are cascade-connected to the slave unit 1A, it is desirable that the transmission power of the downlink system is constant for all the slave units. Therefore, in the present embodiment, the degree of coupling Ci with each of the high-frequency couplers 4-1, 4-2,..., 4-n is determined by the coaxial cable for wiring 3-0, 3-1 and 3 respectively. ,..., 3- (n−1), 15-1, 15-2,. That is, the transmission power of the downlink system of the branching / coupling terminals 5-i (i = 1, 2,... N) of the high-frequency couplers 4-1 4-2,. , The loss of the coaxial cable for wiring, the number of slave units, and the like are determined so as to satisfy the relations of the equations (1) and (2).
[0029]
Pi = di (1-i · Pb) (1)
Where i = 0, 1, 2,..., (N−1)
Ci + 1 = Pb / Pi (2)
Where i = 0, 1, 2,..., (N−1)
[0030]
In the above equations, Pi is the power input to the main line of each of the high-frequency couplers 4-1, 4-2,..., 4-n, Pb is the power at the coupling end 5-i, and di is the coaxial for wiring. This is the loss of the cables 3-0 to 3- (n-1).
When the downlink transmission power is allocated to each slave unit in this manner, the power transmitted from the antenna 10 depends only on the deviation of the lengths of the coaxial cables 15-1 to 15-n. Therefore, if the coaxial cable wiring length in the distributed arrangement is taken into consideration, almost the same level of transmission power can be supplied to all the slave units without causing any problem.
[0031]
The receiving sensitivity in the uplink system is greatly affected by the noise figure immediately below the antenna in the uplink system. In the present embodiment, the improvement is remarkably achieved by inserting and connecting a high-frequency unit (BPF 8 and low-noise amplifier 7) to each communication line of the up-link system of the antenna modules 6-1, 6-2, and 6-n. That is, by disposing the high-frequency unit including the low-noise amplifier 7 having the gain G and the noise factor Fa and the BPF 8 having the noise factor Ff as shown in FIG. Be improved. Hereinafter, this will be described with reference to FIGS. 4 and 5.
FIG. 4 shows the noise figure of each part of the antenna module (for example, 6-1 in FIG. 4, the code suffix is omitted) in the uplink system. The noise figure Fo looking at the input / output terminal 2 side from the antenna connection end 16 is the noise figure just below the antenna when the high-frequency unit (BPF 8 and the low noise amplifier 7) is not provided, that is, the noise figure at the terminal 17 in FIG. They have the same value.
In the case of the present embodiment, the uplink noise figure F at the terminal 17 immediately below the antenna is approximated to the value shown in the equation (3).
F = Ff · (Fa + (2 · Fo−1) / G) (3)
Note that, in the equation (3), the noise figure is represented by an antilogarithm, but may be represented by a logarithm.
[0032]
In the case of a relay device having a very general configuration, the noise figure Fo is about 30 dB (1000 in antilog). The power distributor 13 has a loss of 3 dB with respect to the uplink system, and increases the noise figure by 3 dB (2 in antilogarithm). Accordingly, the noise figure at the output end of the low-noise amplifier 7 in the uplink is 33 dB at 2 Fo (2000 as an antilog). The noise figure 2F0 becomes Fa + (2 · Fo−1) / G at the input end of the low noise amplifier 7 by interposing the low noise amplifier 7 having the noise figure Fa and the gain G. This is well known and will not be described here.
Assuming that Fa is 2 dB (1.58 for an antilog number) and G is 30 dB (1000 for an antilog number), 10 log (Fa + (2 · Fo−1) / G) = 5.5 dB (3.59 for an antilog number). Become.
Therefore, the noise figure F is 6.5 dB (4.5 in the case of an antilogarithm) when the loss Ff of the BPF 8 is 1 dB.
[0033]
Thus, the noise figure F is improved to 6.5 dB as compared with the case where the high-frequency unit is not provided (30 dB). Since the improvement of the noise figure of the uplink system is equivalent to the reduction of the noise power density of the uplink system, the well-known thermal noise (KTB noise: K is the Boltzmann constant, T is the absolute temperature, B By evaluating the bandwidth, the degree of improvement can be found.
[0034]
This will be specifically described as follows.
Assuming that the gain of the entire uplink system is Gs, the noise power density Pf of the uplink system can be approximately approximated to thermal noise per 1 Hz, and can be expressed by equation (4).
Pf = −174 + F + Gs (dBm / Hz) (4)
In the case of the relay apparatus of the present embodiment, since the noise figure F is 6.5 dB, if the gain Gs is 30 dB, the following is obtained.
Pf = −174 + 6.5 + 30 = −137.5 (dBm / Hz)
On the other hand, the noise power density by the conventional antenna module under the same conditions is as follows.
Pf = −174 + 30 + 30 = −114 (dBm / Hz)
[0035]
As described above, by inserting the high-frequency unit in the uplink system of the antenna module as in the present embodiment, the noise power density is low by 23.5 dB, that is, the reception sensitivity is improved by 23.5 dB. As a result, the signal-to-noise ratio (S / N ratio) of the uplink system is greatly improved, and a communication failure due to deterioration in sensitivity, which has conventionally been a problem, is avoided.
[0036]
DC power is supplied from the base unit 21 to the antenna modules 6-1, 6-2,... Therefore, it is not necessary to prepare a power supply on the side of the slave unit (antenna module), which facilitates expansion of the slave unit (antenna module). Therefore, for example, when a dead zone occurs in a building, a slave unit (antenna module) is provided in the dead zone, and the slave unit and the base unit 21 are connected by a coaxial cable, thereby eliminating the dead zone.
It should be noted that this embodiment has one feature in that DC power is supplied from the master unit 21 to the slave unit side 1A via the coaxial cable 29 or the like. Not only the amplifier 7 but also a high-frequency unit including a circuit or an element for suppressing distortion of a signal waveform or another circuit or an element for improving high-frequency characteristics may be used.
[0037]
<Second embodiment>
Next, a second embodiment of the present invention will be described. In the second embodiment, the master unit 21 is the same as that of the first embodiment, and only the configuration of the slave unit is changed.
FIG. 6 shows an example of the configuration of the slave unit according to the second embodiment.
The difference from the first embodiment is that a variable gain amplifier 12 is arranged in the downlink system of the antenna module 6-1. This operation will be described with reference to a partially enlarged view of FIG. 7 (suffixes of reference numerals are omitted).
[0038]
The first signal from the master unit 21 passes through the input / output terminal 2 of the slave unit 1B, the high-frequency coupler 4-1, the branching / coupling terminal 5-1 and the coaxial cable 15-1 for wiring, and then the distribution / integration terminal 13 To reach. Then, at the distribution / integration end 13, the path is separated into a second path of the downlink system, amplified by the amplifier 12, filtered by the BPF 9, and transmitted from the antenna 10 to the portable terminal.
The amplifier 12 has a detection circuit 12a for detecting the signal level of its own output signal and a comparator 12b for comparing the signal levels. The comparator 12b compares the detection level detected by the detection circuit 12a with a predetermined reference level. And controls the gate voltage of the amplifying transistor based on the comparison result to make the gain variable. By setting the reference level in the comparator 12b in advance, the transmission output from the antenna 10 to the portable terminal can be controlled autonomously (self-control). With such a mechanism, it is possible to suppress the deviation of the transmission power of the downlink system due to the length of the wiring coaxial cable 15 and the like.
The power supply of the amplifier 12 may also use the DC power transmitted from the multiplexer 25 of the master unit 21 through the coaxial cables 29, 3-1, 15-1, similarly to the low noise amplifier 7 and the like of the uplink system. it can.
The same operation is performed for the other antenna modules 6-2,..., 6-n.
[0039]
As described above, in the second embodiment, the BPF 9 and the amplifier 12 having a variable gain function are provided immediately below the antenna of the downlink system, and the output power of the amplifier 12 is self-controlled by the detection signal of the detection circuit 12a. Therefore, a function of limiting the maximum gain of the amplifier 12 can be provided. The deviation of the transmission power of the downlink system depending on the coaxial cable length can be improved by adjusting the amplifier gain of each slave unit. By providing the amplifier 12 with a variable gain function, coaxial cable loss can be compensated, so that the degree of freedom of the installation location is increased and measures against interference waves to other stations can be made.
[0040]
<Third embodiment>
FIG. 8 is a configuration diagram of the master unit when performing wired communication with an optical cable instead of wireless communication with a wireless base station.
The master unit 21B has an input terminal 32 for inputting an optical signal transmitted through the optical cable 33 and converts the input optical signal into the first signal (optical → electrical: O / E) and a photoelectric conversion circuit 30 for guiding the first signal to the amplifier module 24. As for the upstream line system, a photoelectric conversion circuit (electrical → optical: E / O) 31 for converting the second signal output from the amplifier module 24 into an optical signal, and an output terminal 34 for leading the optical signal to the optical cable 35. And is provided.
[0041]
The amplifier module 24, the multiplexer 25, the power supply terminal 26, and the connection terminal 27 are the same as those of the master unit 21 according to the first embodiment shown in FIG.
Since the optical cables 33 and 35 are used, there are advantages that the level of the transmission signal is stable and the noise component can be significantly reduced as compared with the master unit 21 used in the first embodiment. Also, in comparison with the conventional master unit 51 employing the optical cable system, DC power is supplied from the power supply terminal 26 to the multiplexer 25, and this DC power is transmitted to the high-frequency unit on the slave unit side through a coaxial cable. There is an advantage that wiring for power supply is not required.
[0042]
<Fourth embodiment>
In the first to third embodiments, the example of the relay device when a single frequency band is used has been described. However, a configuration corresponding to use in a plurality of frequency bands can be adopted.
For example, FIG. 9 is a configuration diagram of a master unit that communicates with a wireless base station by a wireless method. The master unit 21C is a duplexer 23-1 and an amplifier module 24-1, which are 800 MHz band transmitting / receiving units, a duplexer 23-2 and an amplifier module 24-2, a 1.5 GHz band transmitting / receiving unit, and a 2 GHz band transmitting / receiving unit. It has a duplexer 23-3 and an amplifier module 24-3, and these transmission / reception units are connected to the multiplexer 25 in parallel. An 800 MHz band antenna 73-1 is connected to the duplexer 23-1 through the antenna connection end 72-1. The 1.5 GHz band antenna 73-2 is connected to the duplexer 23-2 through the antenna connection end 72-2. Is connected to the duplexer 23-3, and an antenna 73-3 of a 2 GHz band is connected to the duplexer 23-3 through an antenna connection end 72-3.
The operation of the transmission / reception unit of each frequency band is the same as that of the single frequency band. The multiplexer 25 exchanges the first signal and the second signal and transmits DC power between any of these transmission / reception units and the slave unit.
The master unit 21D shown in FIG. 10 is obtained by changing the wireless communication unit of the master unit 21C in FIG. 9 to a wired communication unit using optical cables 33 and 35.
[0043]
As described above, the relay device of the present invention has been described with the plurality of embodiments, but the scope of the present invention is not limited to the above-described embodiment. For example, in each of the embodiments described above, a case where a plurality of slave units are connected to one master unit has been described. However, one relay unit is connected to one master unit to configure a relay device. You may. Further, the functions of the master unit and the slave unit may be included in one housing without distinguishing the master unit and the slave unit. Further, according to the present invention, it is also possible to arrange a plurality of antenna modules or antenna connection ends only in a portion distant from the base unit and connect these connection ends and the base unit to form a relay device. is there.
Further, the present invention can be applied to any mobile terminal that requires relaying during bidirectional communication with a base station. Therefore, the mobile terminal to be relayed is not limited to a mobile terminal, but is portable. It may be a personal computer.
[0044]
【The invention's effect】
As is apparent from the above description, the relay device of the present invention improves the signal characteristics at the antenna connection end by the high-frequency unit when each slave unit performs wireless communication with a mobile terminal located in the service area. Thus, a communication failure caused by the movement of the mobile terminal can be resolved, and stable mobile communication can be continued.
In addition, since the power supply of the high-frequency unit is transmitted from the master unit through the coaxial cable, there is no need to prepare a power supply on the slave unit side, and the slave unit can be installed simply by laying the coaxial cable. Extension of a slave unit can be realized at low cost.
In addition, since the degree of freedom of the length of the coaxial cable is increased when the slave unit is added, it is possible to suppress deterioration of the receiving sensitivity, suppression of the receiving sensitivity, and the like. Since the degree of freedom of the length of the coaxial cable is increased, the deviation of the transmission power between the slave units can be reduced, and highly accurate transmission power control can be easily performed.
Further, since the above-mentioned effects can be obtained even in a plurality of frequency bands, it is possible to widen the band on the slave unit side, which can contribute to the construction of a highly versatile communication system.
As described above, the effect of the present invention is enormous even though the mechanism is simple and inexpensive.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a parent device of a relay device using a wireless method according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram of a multiplexer included in a master unit.
FIG. 3 is a configuration diagram of a slave unit according to the first embodiment.
FIG. 4 is a partially enlarged view of the antenna module according to the first embodiment.
FIG. 5 is a partially enlarged view of a conventional antenna module.
FIG. 6 is a configuration diagram of a slave unit according to a second embodiment of the present invention.
FIG. 7 is a partially enlarged view of an antenna module according to a second embodiment.
FIG. 8 is a configuration diagram of a parent device (optical cable system) according to a fourth embodiment of the present invention.
FIG. 9 is a configuration diagram of a master unit (wireless system) sharing three frequency bands according to a fourth embodiment of the present invention.
FIG. 10 is a configuration diagram of a master unit (optical cable system) sharing three frequency bands according to a fourth embodiment of the present invention.
FIG. 11 is a diagram showing a relationship between a conventional wireless base station and a relay device using an optical cable system.
FIG. 12 is a configuration diagram of a parent device in a conventional relay device using an optical cable system.
FIG. 13 is a configuration diagram of a conventional master unit using a wireless system.
FIG. 14 is a partially enlarged view of a conventional antenna module using a wireless system.
FIG. 15 is a configuration diagram on the slave side of a conventional relay device using a wireless system.
[Explanation of symbols]
1A, 1B slave unit side
2 I / O terminals
3-0 to (n-1), 15-1 to n, 29 Coaxial cable
4-1 to n high-frequency coupler
5-1 to n Distribution / coupling terminals
6-1 to n antenna module
7 Low-noise amplifier of slave unit
8,9 BPF
10,60,63,73 Antenna
12 Variable gain amplifier
12a detection circuit
12b comparator
16-1 to n, 72-1 to 3-3 antenna connection end
17, 27 connection end
21, 21B, 21C, 21D, 51, 61 Master unit
23 Duplexer
24,54 amplifier module
25,55 multiplexer
26 Power supply terminal
30, 30-1 to 3, 31, 31-1 to 3 photoelectric conversion circuits
32 Input terminal for optical cable
34 Output terminal for optical cable
33, 35 Optical cable
40 Low distortion amplifier (LPA)
41 Base Unit Low Noise Amplifier (LNA)
HI input terminal of high frequency coupler
HO Output terminal of high frequency coupler

Claims (11)

An apparatus for relaying communication between a mobile terminal and a base station,
Having a master unit and a slave unit connected to the master unit by a coaxial cable,
The master unit is
A wireless communication unit that enables wireless communication with the base station, and a wired communication unit that enables passing of a high-frequency signal transmitted and received by the wireless communication unit between the slave unit and the coaxial cable, Transmitting means for transmitting DC power to the slave unit through the coaxial cable,
The slave unit is
Wireless communication means having an antenna connection end for connecting an antenna enabling wireless communication with the mobile terminal, and wired communication enabling transmission and reception of a high-frequency signal by the coaxial cable with the master unit Means, and a high-frequency unit that enhances the signal characteristics at the antenna connection end than without it, wherein the high-frequency unit is operable by DC power transmitted from the master unit.
Mobile communication relay device. An apparatus for relaying communication between a mobile terminal and a base station,
Having a master unit and a plurality of slave units connected to the master unit by a coaxial cable,
The master unit is
Wireless communication means for enabling wireless communication with the base station, and wired communication means for enabling high-frequency signals transmitted and received by the wireless communication means to be transferred between the plurality of slave units via the coaxial cable And transmission means for transmitting DC power to the plurality of slaves through the coaxial cable,
Each of the plurality of slave units is coupled to the coaxial cable at a predetermined degree of coupling at which the power level for signal transmission becomes substantially the same level as the other slave units,
Each child unit is
Wireless communication means having an antenna connection end for connecting an antenna enabling wireless communication with the mobile terminal, and wired communication enabling exchange of a high-frequency signal by the coaxial cable with the master unit Means, and a high-frequency unit that enhances the signal characteristics at the antenna connection end than without it, wherein the high-frequency unit is operable by DC power transmitted from the master unit.
Mobile communication relay device. An apparatus for relaying communication between a mobile terminal and a base station,
Having a master unit and a plurality of slave units connected to the master unit by a coaxial cable,
The master unit is
A first wired communication unit that enables optical communication with the base station, and a signal that is transmitted and received by the first wired communication unit can be transferred between the plurality of slave units via the coaxial cable. A second wired communication unit, and a transmission unit that transmits DC power to the plurality of slave units through the coaxial cable,
Each of the plurality of slave units is coupled to the coaxial cable at a predetermined degree of coupling at which the power level for signal transmission becomes substantially the same level as the other slave units,
Each child unit is
Wireless communication means having an antenna connection end for connecting an antenna enabling wireless communication with the mobile terminal, and wired communication enabling transmission and reception of a high-frequency signal by the coaxial cable with the master unit Means, and a high-frequency unit that enhances the signal characteristics at the antenna connection end than without it, wherein the high-frequency unit is operable by DC power transmitted from the master unit.
Mobile communication relay device. The high-frequency unit of the slave unit includes an amplifier for amplifying an uplink high-frequency signal from the mobile terminal to the base station and a filter for removing unnecessary waves of the amplified high-frequency signal, which are cascaded. is there,
The relay device according to claim 1, 2 or 3. When the noise figure of the amplifier is Fa, the gain of the amplifier is G, the noise figure of the filter is Ff, and the noise figure of the uplink system from the connection end of the antenna when the high frequency unit is absent is Fo, The relay apparatus according to claim 4, wherein a noise factor F of an uplink system viewed from a connection end of the antenna when a high-frequency unit is provided has a relationship of the following equation.
F = Ff · (Fa + (2 · Fo−1) / G) The high-frequency unit included in each of the slave units is configured to include a variable gain amplifier capable of adjusting a signal level of a high-frequency signal of a downlink system from the base station toward the mobile terminal,
The relay device according to claim 1, 2 or 3. The amplifier is a gain self-control type amplifier that autonomously controls its own gain according to the signal level output from itself.
The relay device according to claim 6. The amplifier has a function of limiting downlink transmission power to a predetermined value or less,
The relay device according to claim 7. The wireless communication means of the master unit is configured to include a plurality of transmission / reception units for transmitting and receiving high-frequency signals having different frequencies to and from the base station,
The wired communication means included in the master unit is configured to convert a downstream high-frequency signal output from each of the plurality of transmission / reception units and an upstream high-frequency signal input to each of the plurality of transmission / reception units into one type of signal. Configured to integrate and lead to the coaxial cable,
The relay device according to claim 1. The first wired communication means included in the master unit includes a plurality of transmission / reception units for transmitting / receiving high-frequency signals having different frequencies to / from the base station,
The second wired communication means of the master unit is configured to convert a high-frequency signal in a down direction output from each of the plurality of transmission / reception units and a high-frequency signal in an up direction input to each of the plurality of transmission / reception units into one type. Configured to be integrated into a signal and guided to the coaxial cable,
The relay device according to claim 3. The first wired communication unit includes a photoelectric conversion circuit that enables communication with the base station by an optical cable,
The relay device according to claim 10.

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