JP2002300118A - Wireless communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless communication equipment where an indoor unit 8 acting like a power supply side monitors power supplied to an outdoor unit 7 through a cable 9 so as to control the supply of power without the need for a large-sized and heavy outdoor unit 7 and to cope with occurrence of the disconnection, short-circuiting or a rush current to the cable. SOLUTION: This invention provides the wireless communication equipment where the indoor unit 8 supplies operating power to the outdoor unit 7 via the cable 9, the indoor unit 8 is provided with a power supply section 15, a current detection circuit 23 that monitors a current flowing from the power supply section to the cable 9, and a control section 25 that stops supply of power from the power supply section 15 in response to the current through the cable in excess of an upper limit and a lower limit specified value, and drives a power supply control element 22 depending on the result of current monitor so as to stabilize the cable current.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a first unit having a function of processing radio communication by an antenna,
The present invention relates to a wireless communication apparatus of a type in which a second unit having a function of processing communication with a communication network on the backbone side is separated and these units are connected via a communication cable. It relates to control of electric power supplied through a cable to the first unit.

[0002]

2. Description of the Related Art In a radio communication apparatus, it is required to install an antenna in a place where visibility is not affected by propagation of radio waves. In some cases, it is necessary to separate the antenna device portion from the device portion and connect the antenna device portion with a communication cable, thereby reducing the size and weight of the antenna device portion and making it easy to install the antenna device portion on a tower or a rooftop of a building. For example, in a subscriber wireless access system called an FWA (fixed wireless access) system, it is required that a wireless communication device forming a base station or a subscriber station be divided into units as described above.

An example of a wireless access system is shown in FIG.
Is a system for performing wireless communication between a base station device 1 and a subscriber station device 2 installed on each subscriber side,
The base station device 1 is connected to a public communication network 4 via a cable 3, and each subscriber station device 2 is connected to a subscriber communication network (not shown) such as a LAN possessed by the subscriber. Wireless communication with the subscriber station device 2 realizes communication between subscriber communication networks and communication between the subscriber communication network and the public communication network 4.

[0004] The base station apparatus 1 and the subscriber station apparatus 2 that perform such wireless communication include an apparatus portion (hereinafter also referred to as an outdoor unit) 7 having a function of processing wireless communication by an antenna 6 and a public unit. A device portion having a function of processing communication with a communication network on the backbone side such as a communication network or a subscriber communication network (hereinafter, also referred to as an IDU: indoor unit) 8
Are connected via a communication cable 9, and the ODU 7 is connected to the roof of a building 10 or the tower 1 as shown in FIG.
1 Install the antenna at an outdoor high place with good visibility such as above
, While the IDU 8 is building 10
It is installed indoors to avoid external factors such as temperature changes and to facilitate maintenance.

FIG. 8 shows a configuration of a division type radio communication apparatus constituting the base station apparatus 1 and the subscriber station apparatus 2.
The ODU 7 is provided with a wireless unit (RF unit) 12 for performing wireless communication processing mainly using the antenna 6, and the IDU 8 is provided with a communication unit 13 for performing data communication with a communication network on the backbone side and a general wireless communication device. A control unit 14 for performing control is provided. The IDU 8 is provided with an operation power supply 15 for supplying power to the IDU 8 and the ODU 7, and operation power is supplied to the ODU 7 through the cable 9. In other words, the ODU 7 installed at an outdoor high place is reduced in size and weight by eliminating functions not related to wireless communication as much as possible, and secures an installation place and facilitates installation work at a high place.

[0006]

As described above, in the wireless communication apparatus in which the ODU 7 mainly having the wireless communication processing function and the IDU 8 mainly having the communication processing function with the backbone side are connected by the cable 9, the IDU 8 Although the operating power is supplied to the ODU 7 through the cable 9, the ODU 7 is installed at an outdoor high place apart from the IDU 8, so that the cable 9 becomes long, such as several tens of meters to several hundreds of meters.

As described above, since the cable length is long and such a cable is laid outdoors or at a high place exposed to changes in the external environment such as the outdoors or at a high place, the cable 9 is disconnected or short-circuited. Could be In such a case, the function of the wireless communication device including the ODU 7 and the IDU 8 is stopped, and the communication service may be stopped. Also, when the power is turned on after installation or maintenance, particularly when the ODU7 is equipped with a voltage converter such as an AC / DC converter, an excessive rush occurs when the power is turned on after installation or maintenance. Current may flow from the IDU 8 through the cable 9 and cause abnormal heating or functional failure of the ODU 7.

[0008] Here, in a subscriber station apparatus having a configuration in which an outdoor unit (ODU) and an indoor unit (IDU) are connected by a cable, the ODU responds to the input voltage with respect to the operating power supplied from the IDU through the cable. An invention for performing the control process is described in Japanese Patent Application Laid-Open No. 2000-1970083. However, in this conventional invention,
The ODU is provided with a voltage detection unit for detecting an input voltage, a setting unit for a voltage detection threshold value, and a notification unit for notifying a base station of a cable abnormality detected based on the input voltage. The size and weight have been increased, and this has conflicted with the demand for an ODU that is desired to be reduced in size and weight in order to facilitate the installation work.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned conventional circumstances, and a power supply unit monitors the power supplied to the other unit and controls the power supply to a cable disconnection accordingly. The purpose is to: Another object of the present invention is to monitor the power supplied to the other unit in the unit on the power supply side, and control the power supply in response to a short circuit in the cable accordingly.

Further, the present invention monitors the power supplied to the other unit in the unit on the power supply side,
Accordingly, an object of the present invention is to control power supply in response to generation of an excessive supply current. Another object of the present invention is to provide a wireless communication device suitable for application to a base station device or a subscriber station device of a wireless access system.
Further objects of the present invention will be apparent in the following description.

[0011]

According to the present invention, there is provided a first unit having a function of processing wireless communication by an antenna,
A wireless communication device that connects a second unit having a function of processing communication with a backbone side communication network via a cable and supplies operating power from the second unit to the first unit via the cable The second unit includes a power supply unit, a monitoring unit that monitors a current flowing through the cable from the power supply unit to the first unit, and a cable in a state where power is supplied from the power supply unit to the first unit. And a control unit for stopping the power supply from the power supply unit when the current flowing through the power supply becomes equal to or less than a predetermined lower limit specified value.

Therefore, when the cable current is equal to or less than the lower limit specified value, the second unit detects a situation such as a disconnection of the cable or a connection failure, and stops the power supply, thereby causing abnormal heating of the second unit. It is possible to prevent a failure due to the above. Since the detection and control function is provided in the second unit having a relatively free installation environment such as an indoor environment, the first unit whose installation environment is restricted such as an outdoor high place is particularly special. It is possible to maintain a small and lightweight configuration without making any changes.

According to the present invention, a first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable. Wireless communication device for supplying operating power from the second unit to the first unit via a cable, the second unit having a power supply unit and a cable from the power supply unit to the first unit. A monitoring unit that monitors a flowing current; and a power supply unit that supplies power from the power supply unit when a current flowing through the cable becomes equal to or more than a predetermined upper limit specified value while power is supplied from the power supply unit to the first unit. And a control unit for stopping.

Therefore, when the cable current is equal to or more than the upper limit specified value, a situation such as a short circuit of the cable or a failure on the first unit side is detected on the second unit side, and the first power supply is stopped. A failure due to abnormal heating of the unit can be prevented. Since the detection and control function is provided in the second unit having a relatively free installation environment such as an indoor environment, the first unit whose installation environment is restricted such as an outdoor high place is particularly special. It is possible to maintain a small and lightweight configuration without making any changes.

According to the present invention, a first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable. Wireless communication device for supplying operating power from the second unit to the first unit via a cable, the second unit having a power supply unit and a cable from the power supply unit to the first unit. A monitoring unit for monitoring the flowing current, and stopping the power supply from the power supply unit when the current flowing through the cable becomes equal to or more than a predetermined upper limit specified value when the power supply from the power supply unit to the first unit is started. And a control unit.

Therefore, the second unit detects excessive supply power (rush current) generated when the power is turned on because the cable current is equal to or more than the upper limit specified value, and stops the power supply. Failure due to abnormal heating of the unit can be prevented beforehand. And
Since the detection and control functions are provided in the second unit whose installation environment is relatively free, such as indoors, the first unit whose installation environment is restricted, such as an outdoor high place, is particularly changed. Therefore, a compact and lightweight configuration can be maintained without adding any additional components.

Also, the present invention provides a first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network via a cable. Wireless communication device for supplying operating power from the second unit to the first unit through a cable, the second unit includes a power supply unit, and a power supply unit to the first unit through a cable. A power adjustment unit that adjusts the supplied power, and a control unit that monitors the current flowing through the cable and controls the power adjustment unit to limit the cable current to a predetermined upper limit specified value or less,
Is provided.

Therefore, the excessive supply power generated in the operating state is detected on the second unit side, and the supply power is stabilized by limiting the cable current to the upper limit specified value or less, and the first unit is abnormally heated. It is possible to prevent a failure due to the above. Since the detection and control function is provided in the second unit having a relatively free installation environment such as an indoor environment, the first unit whose installation environment is restricted such as an outdoor high place is particularly special. It is possible to maintain a small and lightweight configuration without making any changes.

Here, in the wireless communication apparatus according to the present invention,
The power adjustment unit is a transistor element that adjusts a current output to the cable, and the control unit detects a current value flowing through the transistor and outputs a detection voltage that decreases as the current value increases. An output circuit for applying a gate voltage corresponding to the voltage to the transistor element, and increasing or decreasing the gate voltage of the transistor element in opposition to an increase or decrease in the detected current value, thereby setting the cable current to a predetermined upper limit specified value. It is also possible to limit to the following.

In the wireless communication apparatus according to the present invention, in addition to the above-described power supply stabilizing function, the current flowing through the cable when the power supply from the power supply unit to the first unit is started is supplied to the second unit. May be provided with a power supply control unit that stops the power supply from the power supply unit when the power supply value becomes equal to or more than the predetermined upper limit specified value.
Supply of an inrush current to the other unit may be prevented.

Further, in the wireless communication apparatus according to the present invention, in addition to the above-described power supply stabilizing function and inrush current preventing function, power is supplied from the power supply unit to the first unit to the second unit. A power supply control unit that stops the power supply from the power supply unit in response to the current flowing through the cable in a state where the current is equal to or more than the predetermined upper limit specified value. Supply of an excessive current to the unit may be prevented.

Further, in the wireless communication apparatus according to the present invention, in addition to the above-mentioned power supply stabilizing function, inrush current preventing function, and excessive current preventing function, the second unit and the power supply section to the first unit can be used. A power supply control unit may be provided which stops the power supply from the power supply unit when the current flowing through the cable in a state where the power is supplied becomes equal to or less than a predetermined lower limit specified value. You may make it possible to deal with a disconnection, a contact failure, etc.

In the wireless communication apparatus according to the present invention, the second unit may be provided with a notifying section for notifying that the power supply by the power supply control section has been stopped. Alternatively, the maintenance work may be performed promptly by transmitting an abnormality report to a manager. Further, since the wireless communication device according to the present invention can be implemented without making any special changes to the first unit, in particular, an outdoor unit (ODU) in which the first unit is installed at a high place outdoors The present invention is suitably applied to a base station device or a subscriber station device of a wireless access system used as a wireless access system.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be specifically described based on an embodiment in which the present invention is applied to a base station apparatus of a subscriber radio access system. The present invention is not limited to the subscriber station apparatus of the subscriber wireless access system and the first unit having the function of processing the wireless communication by the antenna, as well as the subscriber station apparatus of the subscriber wireless access system, as in the following embodiments. And a second unit having a function of processing communication with the backbone communication network via a cable, and the second unit via the cable.
It can be widely applied to wireless communication devices of a type that supplies operating power from a unit to a first unit.

In the embodiment described below, in a wireless access system, a first unit having a wireless communication function mainly by an antenna is an ODU (outdoor unit),
A second unit mainly having a communication function with a backbone communication network such as a LAN on the subscriber side is an IDU (indoor unit), and the same parts are the same with reference to FIGS. The reference numerals are used, and the overlapping description is omitted.

FIG. 1 shows a configuration of a base station apparatus 1 according to one embodiment of the present invention, wherein an ODU 7 and an IDU 8 are connected by a coaxial cable 9. ODU7 and IDU
Reference numeral 8 denotes a communication of information to be transmitted such as audio information, image information, and text information by a coaxial cable 9 and an ODU 7
Communication of information related to control with U8, and furthermore, ID
The operation power is also transmitted from U8 to ODU7. The present invention is not limited to the connection using the coaxial cable, and the ODU 7 and the IDU 8 may be connected by a cable for operating power transmission separately from the cable for information communication. Similar effects can be obtained.

As shown in FIG. 8, the ODU 7 is provided with a converter 20 for converting the operating power transmitted from the IDU 8 through the cable 9 into a voltage, in addition to the RF unit 12 for performing the radio communication processing by the antenna 6. I have. In addition,
The IDU 8 is provided with a power supply terminal 19. One end of the cable 9 having one end connected to the power supply terminal 19 is connected to the converter 20, and operating power transmitted from the IDU 8 is input to the converter 20. .

The IDU 8 includes a communication unit (not shown), a control unit 14, a stabilized power supply having an on / off switch terminal serving as a power supply 15, and a cable state display for notifying an abnormality in supply power. A part 21 is provided.
The cable status display unit 21 of the present embodiment is composed of a plurality of LEDs for displaying the above status such as a cable disconnection or a cable short circuit by lighting up the LED. , Or a configuration in which an abnormality notification is transmitted to the administrator wirelessly or via a wire, as long as the occurrence of an abnormal state can be reported in a manner as close to the administrator as possible.

Here, the control unit 14 of the IDU 8 has a specific configuration for performing the control processing according to the present invention. That is, the control unit 14 adjusts the amount of operating current input from the stabilized power supply 15 to the power supply terminal 19 (that is, the cable 9) according to the power supply control element drive signal 01 and the power supply control element 22 and the power supply terminal 19. A current detection circuit 23 that constantly monitors the amount of current flowing from the cable 9 to the cable 9 and outputs a power supply control element drive signal 01 according to the detection result, and constantly monitors the power supply control element drive signal 01 and the voltage of the signal 01 The power supply control element drive signal monitoring unit 24 that outputs the disconnection detection signal 02, the short-circuit detection signal 03, and the inrush detection signal 04 according to the value, according to the input of the disconnection detection signal 02, the short-circuit detection signal 03, or the inrush detection signal 04 In order to turn off the stabilizing power supply 15 and to notify the cable disconnection or the cable short-circuit in accordance with the signal, the cable status display unit 21 displays the LE. And a power control unit 25 for lighting.

In this embodiment, a specified voltage value for detecting the occurrence of an excessive current such as a cable disconnection, a cable short circuit or an inrush current is set in the power supply control element drive signal monitoring unit 24. Power supply control element drive signal 0
The following power supply control processing is performed by comparison with the voltage value of 1. As described later, the power supply control element 22 of this example has a MOS whose resistance value decreases (that is, the operating power transmitted to the cable 9 increases) when the voltage value of the power supply control element drive signal 01 increases. -FET (voltage effect transistor).

FIG. 4 is a flowchart for explaining the operation of cable short-circuit detection and supply power control processing. First,
The stabilized power supply 15 is turned on (step S1), and the stabilized power supply 15 is connected to the terminal 1 via the power supply control element 22.
9 (cable 9), the power supply for operating the ODU 7 is started, and the voltage value of the power supply control element drive signal 01 is equal to or higher than a predetermined threshold value (that is, the supply current amount flowing through the power supply control (Step S2), the normal operation state is set. That is, the power supply control element drive signal monitoring unit 24 monitors the power supply control element drive signal 01 to grasp the normal operation state.

In such a normal operation state, the power supply control element drive signal monitoring section 24 monitors the power supply control element drive signal 01, and if a cable short circuit occurs, the amount of cable current increases. , Current detection circuit 2
3 decreases the voltage value of the power supply control element drive signal 01 so as to increase the resistance value of the power supply control element 22 against the detected increase in the amount of cable current. When the following is detected (Step S3), the power supply control element drive signal monitoring unit 24 outputs the short-circuit detection signal 03 to the power supply control unit 25, and the power supply control unit 25 turns off the stabilized power supply 15 and The LED indicating the short-circuit state is lit on the state display section 21 (step S4).

Therefore, if a cable short circuit occurs during operation, the power supply 15 is turned off and the power supply is stopped by the processing of the IDU 8, so that a situation such as abnormal heating due to an excessive current is prevented. be able to. In this example using the power supply control element 22 having a characteristic in which the voltage value of the drive signal 01 and the resistance value are opposite to each other, the short-circuit detection voltage is determined when a considerably large cable current is detected as shown in FIG. It is set to the voltage value of the element drive signal 01 (a considerably low value).

FIG. 5 is a flowchart for explaining the operation of cable disconnection detection and supply power control processing. First,
When the stabilized power supply 15 is turned on (step S11), power supply for operating the ODU 7 from the stabilized power supply 15 is started, and the voltage value of the power supply control element drive signal 01 becomes equal to or higher than a predetermined threshold value. By the way (step S1
2) A normal operation state is set, and the power supply control element drive signal monitoring unit 24 monitors the power supply control element drive signal 01 to grasp the normal operation state.

In such a normal operation state, the power supply control element drive signal monitoring section 24 monitors the power supply control element drive signal 01, and if a cable break occurs, the amount of cable current decreases or Becomes zero,
Since the voltage value of the power supply control element drive signal 01 is increased so as to decrease the resistance value of the power supply control element 22 against the decrease in the amount of cable current detected by the current detection circuit 23, the signal voltage becomes a predetermined value. When detecting that the voltage is equal to or higher than the disconnection detection voltage (step S13), the power supply control element drive signal monitoring unit 24 outputs a disconnection detection signal 02 to the power supply control unit 25, and the power supply control unit 25 turns off the stabilized power supply 15. At the same time, the LED indicating the disconnection state is lit on the cable state display section 21 (step S14).

Therefore, if a cable break occurs during operation, the power supply 15 is turned off and the power supply is stopped by the processing on the IDU 8 side, thereby preventing a situation such as abnormal heating due to an excessive current. be able to. In this example using the power supply control element 22 having a characteristic in which the voltage value of the drive signal 01 and the resistance value are opposite to each other, the disconnection detection voltage is determined when the cable current value is detected to be considerably small as shown in FIG. Is set to the voltage value of the element drive signal 01 (a considerably large value).

Here, the current detection circuit 23 changes the voltage of the power supply control element drive signal 01 based on the detected current value so that the cable current value does not become too large or too small. That is, when the detected current value is excessively larger than a predetermined threshold value (in this example, a current value corresponding to the power supply control element threshold voltage shown in FIG. 3), the resistance of the element 22 is reduced by decreasing the voltage of the drive signal 01. When the detected current value is smaller than a predetermined threshold value, the drive signal 01 is increased.
, The resistance value of the element 22 is reduced and the cable current value is increased. Therefore, by the voltage control of the drive signal 01, the power supplied to the ODU 7 through the cable 9 during operation is almost stabilized to a certain specified value, and a satisfactory operation of the ODU 7 is guaranteed.

The drive signal 0 by the current detection circuit 23
1 is also performed when the power is turned on by turning on the stabilized power supply 15. Further, when the power is turned on, the power supply control element drive signal monitoring unit 24 and the power control unit 25
Performs the inrush current limiting process. That is, the current detection circuit 23 lowers the voltage of the drive signal 01 when the current value detected due to the rush current caused by turning on the power is excessively large. The signal monitoring unit 24 outputs the inrush detection signal 04, whereby the power supply control unit 25 turns off the stabilized power supply 15. Therefore, even if an inrush current occurs when the power is turned on, the power is immediately turned off, so that a situation such as abnormal heating due to an excessive current can be prevented.

FIG. 2 shows a more specific circuit configuration example of the current detection circuit 23 and the power supply control element 22 described above. In the figure, 31, 33, 35, 36, and 37 are resistance elements, 32 is an operational amplifier that outputs a voltage signal corresponding to a difference between two inputs, and 34 is an operational amplifier 32
Is a transistor element whose base current is controlled by the output of the power supply control element 2.
The transistor element that constitutes 2 is a MOS-FET.

The current detecting circuit 23 detects the current (Iin) flowing through the cable 9 by the resistor 31 (R31) for detecting the current.
Is converted to a current detection voltage (V31 = R31 × Iin). The operational amplifier 32 controls the base current of the transistor 34 so that the current (I33) flows through the resistor 33 (R33) and the voltage (V
33 = R33 × I33) is controlled to be equal to the current detection voltage (V31). The current (I) is connected to the resistor 35 (R35).
33) flows, the relationship between the current detection output voltage (Vout) and the current (Iin) flowing through the cable 9 is expressed by the following equation: Vout = VCC-R35 × I33 = VCC-R35 × (R31 /
R33) × Iin.

FIG. 3 shows the current detection output voltage (Vou
t) and the current (Iin) flowing out of the cable 9 are shown. As can be seen from the graph, the current detection circuit 23
Has a characteristic that the current detection output voltage (Vout) decreases as the current (Iin) flowing into the cable 9 increases. Then, the current detection output voltage (Vout) is divided by the resistor 36 and the resistor 37 and the power supply control element drive signal 01
Is applied to the gate of the power supply control element transistor 22. Since the transistor 22 has a characteristic that the resistance value decreases as the drive voltage increases, the current (Iin) flowing out to the cable 9 is a certain value. The value can be stabilized, and the value of the inrush current flowing out to the cable 9 can be reduced together with the above-described power-off process even when an inrush current occurs when the power is turned on.

[0042]

As described above, according to the present invention,
The power supply control processing related to power supply, such as power-off processing for cable disconnection, power-off processing for cable short-circuit, stable supply of power to the first unit (ODU), and handling of inrush current, is performed by the first unit. This can be realized without requiring a special configuration change. Therefore, stable operation of the system by supply power control can be realized without increasing the size and weight of the first unit, and it is possible to maintain good workability in installing the first unit. In particular, the ODU which needs to be installed at a high place in the wireless access system is reduced in size and weight, and the installation work of the base station device and the subscriber station device used in the wireless access system becomes easy.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a base station apparatus according to one embodiment of the present invention.

FIG. 2 is a circuit diagram of a current detection circuit and a power supply control element according to one embodiment of the present invention.

FIG. 3 is a graph showing a relationship between a current detection voltage and a cable current according to one embodiment of the present invention.

FIG. 4 is a flowchart illustrating processing for a cable short-circuit according to an embodiment of the present invention.

FIG. 5 is a flowchart illustrating processing for cable disconnection according to an embodiment of the present invention.

FIG. 6 is a system configuration diagram illustrating a wireless access system.

FIG. 7 is a diagram illustrating an installation state of a wireless access system.

FIG. 8 is a diagram illustrating a configuration of a base station device and a subscriber station device.

[Explanation of symbols]

1: base station device, 2: subscriber station device, 6: antenna,
7: Outdoor unit (ODU), 8: Indoor unit (I
DU), 9: coaxial cable, 15: stabilized power supply, 2
1: cable status display unit, 22: power supply control element,
23: current detection circuit, 24: power supply control element drive signal monitoring unit, 25: power supply control unit,

Continued on the front page F term (reference) 5G053 AA01 AA02 AA07 BA01 BA04 CA01 CA04 DA01 DA03 EC03 FA06 5G065 BA04 BA05 BA07 DA07 EA01 GA07 JA02 KA05 LA02 MA09 NA04 PA01 5K042 AA08 CA06 CA24 DA35 EA03 FA29 GA02 KA02 NA01

Claims (10)

[Claims] 1. A first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable, In a wireless communication apparatus for supplying operating power from a second unit to a first unit via a cable, the second unit includes a power supply unit and a monitor that monitors a current flowing through the cable from the power supply unit to the first unit. A control unit that stops power supply from the power supply unit in response to a current flowing through the cable being equal to or less than a predetermined lower limit specified value while power is being supplied from the power supply unit to the first unit; A wireless communication device comprising: 2. A first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable, In a wireless communication apparatus for supplying operating power from a second unit to a first unit via a cable, the second unit includes a power supply unit and a monitor that monitors a current flowing through the cable from the power supply unit to the first unit. A control unit that stops power supply from the power supply unit in response to a current flowing through the cable being equal to or more than a predetermined upper limit specified value while power is being supplied from the power supply unit to the first unit; A wireless communication device comprising: 3. A first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable, In a wireless communication apparatus for supplying operating power from a second unit to a first unit via a cable, the second unit includes a power supply unit and a monitor that monitors a current flowing through the cable from the power supply unit to the first unit. And a control unit that stops the power supply from the power supply unit when the current flowing through the cable when the power supply from the power supply unit to the first unit starts is equal to or more than a predetermined upper limit specified value. A wireless communication device characterized by the above-mentioned. 4. A first unit having a function of processing wireless communication by an antenna and a second unit having a function of processing communication with a backbone communication network are connected via a cable, In a wireless communication device that supplies operating power from a second unit to a first unit via a cable, the second unit adjusts a power supply unit and power supplied from the power supply unit to the first unit through the cable. A wireless communication device comprising: a power adjustment unit; and a control unit that monitors a current flowing through the cable and controls the power adjustment unit to limit the cable current to a predetermined upper limit or less. 5. The wireless communication device according to claim 4, wherein the power adjustment unit is a transistor element that adjusts a current output to the cable, and the control unit detects a current value flowing through the transistor and detects the current value. Has a detection circuit that outputs a detection voltage that decreases as the detection voltage increases, and an output circuit that applies a gate voltage corresponding to the detection voltage to the transistor element. A wireless communication device, wherein a cable current is limited to a predetermined upper limit or less by increasing or decreasing a gate voltage. 6. The wireless communication device according to claim 5, wherein when a power supply from the power supply unit to the first unit starts, a current flowing through the cable becomes equal to or more than a predetermined upper limit specified value. A wireless communication device comprising a power supply control unit for stopping power supply from a wireless communication device. 7. The wireless communication device according to claim 5, wherein a current flowing through the cable in a state where power is supplied from the power supply unit to the first unit has exceeded a predetermined upper limit specified value. A wireless communication device comprising a power supply control unit for stopping power supply from a power supply unit in response to the request. 8. The wireless communication apparatus according to claim 5, wherein a current flowing through the cable while power is being supplied from the power supply unit to the first unit has a predetermined lower limit. A wireless communication device comprising: a power supply control unit that stops power supply from a power supply unit when the power supply value becomes equal to or less than a value. 9. The wireless communication device according to claim 6, wherein the second unit has a notifying unit that notifies a stop of power supply by the power control unit. A wireless communication device characterized by the above-mentioned. 10. The wireless communication device according to claim 1, wherein the base station device or the subscriber station device of a wireless access system wirelessly connects a public communication network and a subscriber communication network. Wherein the first unit is installed at a high place outdoors.