JP2004140820A - Radio equipment for outdoor installation - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio apparatus for outdoor installation which makes electronic equipment such as communication equipment stored in a cabinet function without any trouble. <P>SOLUTION: The radio apparatus for outdoor installation has a radio transmission/reception part which performs modulation/demodulation processing and a common part which controls an operation of the radio transmission/reception part, and it is characterized in that the radio transmission/reception part is installed to the common part so that it is exposed to the open air. <P>COPYRIGHT: (C)2004,JPO

Description

The present invention relates to a wireless device installed outdoors, and particularly to an outdoor wireless device that houses electronic devices such as communication devices and is installed outdoors.

In recent years, in order to realize communication enabling transmission and reception of high-speed and large-capacity information, electronic devices of wireless devices are required to have large capacity. Therefore, the power consumption of the electronic device increases, and the heat generation per unit volume is constantly increasing.

か か る In addition, such electronic devices are often housed in a housing and installed outdoors such as on the roof of a building. Therefore, there is a demand for a wireless device that can withstand an outdoor environment such as waterproofing of an electronic device and has excellent workability in an outdoor environment.

FIG. 1 is an exploded perspective view of a conventional wireless device 1 for outdoor installation. Referring to FIG. 1, a conventional wireless device 1 for outdoor installation has a substantially box-like shape, and has a housing in which electronic devices such as a transmission / reception panel 2, a control modulation / demodulation panel 3, and a duplexer 4 are mounted. It has a configuration including the body 19. The housing 19 ensures waterproofness of the electronic device mounted inside. In addition, a sunshade cover 5 is provided on an upper portion of the housing 19 to shield the housing 19 from sunlight.

The door 19 is provided on the front of the housing 19, and the back 8 is provided on the back. The door 6 is opened when the electronic device mounted inside the housing 19 is maintained, expanded or replaced.

A large number of radiating fins 7 are provided in parallel on the back surface 8. Since the electronic equipment such as the transmitting and receiving panel 2 mounted inside the housing 19 transmits a large amount of information and consumes a large amount of power and heat, the transmitting and receiving panel 2 and the like abut on the back surface 8 having the radiation fins 7. It has been. Therefore, the electronic device such as the transmitting and receiving panel 2 radiates heat by applying heat to the radiating fins 7 provided on the back surface portion 8.

However, there are the following problems when housing the electronic device having a large amount of heat, such as the transmission / reception panel 2, in the above-described housing 19 and installing the housing 19 in an outdoor environment.

That is, when the heat generated from the electronic device such as the transmission / reception panel 2 or the like cannot be effectively dissipated to the outside and the electronic device in the housing 19 cannot be effectively cooled, the electronic device in the housing 19 cannot be cooled. The temperature may rise and the electronic device may malfunction. As described above, since the transmitting and receiving panel 2 and the like, which are high heat-generating components mounted in the housing 19, dissipates heat only by the radiating fins 7 provided on the back surface portion 8, the amount of heat dissipated is limited. Therefore, in the conventional wireless device 1 for outdoor installation, the heat radiation effect of the electronic device mounted inside is not necessarily sufficient.

(4) If rainwater or the like falls on the housing 19 and moisture adheres to an electronic device such as the transmission / reception board 2 mounted in the housing 19, the function may be deteriorated or malfunction may occur. In the conventional wireless device 1 for outdoor installation, the housing 19 and the door 6 are used to waterproof the electronic device such as the transmission / reception panel 2, but it is not always perfect, and it is necessary to further improve the waterproofness of the electronic device. is there.

Further, as described above, every time the electronic equipment mounted inside the housing 19 such as the transmission / reception board 2, the control modulation / demodulation board 3, the duplexer 4, etc. I needed to open and close. Accordingly, the conventional wireless device for outdoor installation 1 has a problem in workability, and a wireless device for outdoor installation that can be easily operated has been demanded.

Therefore, an object of the present invention has been made in view of the above problems, and to provide a wireless device for outdoor installation that enables electronic devices such as communication devices housed in a housing to function without any trouble. It is in.

The object is to provide a wireless transmission / reception unit for performing modulation / demodulation processing and a common unit for controlling the operation of the wireless transmission / reception unit, wherein the wireless transmission / reception unit is attached to the common unit so as to be exposed to outside air. Achieved by a wireless device.

The common unit includes a transmission / reception unit interface unit including a connector, the wireless transmission / reception unit includes a common unit interface unit including a connector on a side attached to the common unit, and the connector of the common unit interface unit. The wireless transmission / reception unit may be electrically connected to the common unit by fitting into the connector of the interface unit for the wireless transmission / reception unit.

A waterproof member may be provided on a surface of the wireless transmitting / receiving unit where the common unit interface unit comes into contact with the wireless transmitting / receiving unit interface unit of the common unit.

Further, the wireless transmitting and receiving unit includes a housing having an electronic device mounted therein and a heat radiating member on a side attached to the common unit, and the electronic device is directly or indirectly attached to the housing or the heat radiating member. The heat generated from the electronic device in contact with the electronic device may be transmitted to outside air via the housing or the heat radiating member.

According to the outdoor wireless device of the present invention, electronic devices such as communication devices housed in the housing can function without any trouble.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 2 is an exploded perspective view showing the appearance of the outdoor-installed wireless device 10 according to the present invention. Referring to FIG. 2, the outdoor installation wireless device 10 includes a substantially rectangular parallelepiped (box-shaped) common unit 20 and a land-cell-type wireless transmitting / receiving unit 50-attached to the right side surface 23 of the common unit 20. 1 and 50-2, and a school cell-type wireless transceiver 50-3 and 50-4 attached to the left side surface of the common unit 20.

FIG. 3 is a diagram showing the appearance of the common unit 20, FIG. 3- (a) is a diagram viewed from the Y2-Y1 direction in FIG. 2, and FIG. 3- (b) is a diagram showing X1- FIG. 3C shows a view seen from the X2 direction, and FIG. 3C shows a view seen from the Y1-Y2 direction in FIG.

よ う As shown in FIG. 3A, two antenna interface units 22 are vertically arranged in parallel on the front surface 21 of the common unit 20. The other end of a waveguide (not shown) for transmitting a microwave (SHF) or the like, one end of which is connected to the antenna, is connected to the antenna interface unit 22.

As shown in FIG. 3B, below the right side surface 23 of the common unit 20, a transmission / reception unit interface 24 for transmitting / receiving a radio signal or the like is provided in parallel on the left and right sides. The two side interfaces for the transmission / reception unit are also provided on the left side surface of the common unit 20 (the surface of the common unit 20 viewed from the X2-X1 direction in FIG. 2), similarly to the right side surface unit 23. .

As will be described later, when the wireless transmission / reception units 50-1 to 50-4 are attached to the common unit 20, the transmission / reception unit interface unit 24 becomes the common unit interface unit 55 of the wireless transmission / reception units 50-1 to 50-4 described later. And functions as an interface between the common unit 20 and the wireless transmission / reception units 50-1 to 50-4.

By the way, up to four wireless transmission / reception units 50-1 to 50-4 can be attached to the common unit 20, but it is not necessary to attach all four units. For example, only two units may be attached to the common unit 20. In this case, the two transmission / reception unit interface units 24 that are not fitted with the common unit interface unit 55 because the wireless transmission / reception unit is not attached are covered with lids for waterproofing.

Next, the structure of the transmission / reception unit interface unit 24 will be described. Referring to FIG. 3B, the transmission / reception unit interface unit 24 includes a first connector unit 300, a second connector unit 320, and a third connector unit 340. The first connector part 300 is provided with a first connector fitting part 300-1 at substantially the center, and guide pins 300-2 are provided on the left and right sides in the vertical direction on the paper surface of FIG. The structures of the second connector portion 320 and the third connector portion 340 will be described later.

送 受 信 Further, above the right side surface portion 23 of the common portion 20, a transmission / reception portion bearing portion 25 is provided in parallel on the left and right. As shown in FIG. 3A, the transmission / reception is also performed on the left side surface of the common unit 20 (the surface of the common unit 20 viewed from the X2-X1 direction in FIG. 2), similarly to the right side surface unit 23. A part bearing is provided. The wireless transmission / reception units 50-1 to 50-4 are rotated by hooking the common unit hook shaft member 56 of the wireless transmission / reception units 50-1 to 50-4, and the transmission / reception unit interface unit 24 and the common unit interface unit 55 The wireless transmission / reception units 50-1 to 50-4 are attached and fixed to the common unit 20 in conjunction with the fitting. The structure for attaching the wireless transmission / reception units 50-1 to 50-4 to the common unit 20 will be described later.

Furthermore, as shown in FIG. 3C, eight external connectors 27 are provided on the back surface 26 of the common unit 20. An external device (not shown) is connected to the external connector 27. Two external connectors 27 are required for one wireless transmitting / receiving unit 50-1 to 50-4 attached to the common unit 20. One is for input and the other is for output. The external connector 27 is used in pairs for input and output. A power signal supply unit 28 for supplying power and a signal to the common unit 20 is provided below the rear unit 26 of the common unit 20.

Next, the internal structure of the common unit 20 will be described. 4 is a diagram showing the internal structure of the common unit 20, FIG. 4- (a) is a cross-sectional view when viewed from the Z1-Z2 direction in FIG. 2, and FIG. 2 is a cross-sectional perspective view when viewed from the X1-X2 direction.

（Referring to FIG. 4A, a power supply unit 30 and a plurality of switching units 31 are provided in the common unit 20 in a continuous manner in the Y1-Y2 direction in FIG. Further, a control unit 32 is provided alongside the power supply unit 30 and the plurality of switching units 31 in the X1-X2 direction in FIG.

The power supply unit 30 converts a primary power supply into a secondary power supply and supplies power to each electronic component mounted on the common unit 20. The control unit 32 monitors each of the wireless transmission / reception units 50-1 to 50-4 attached to the common unit 20 via the transmission / reception unit interface unit 24, selects a high-quality clock signal, and It is distributed to the transmission / reception units 50-1 to 50-4.

When a plurality of wireless transmission / reception units 50-1 to 50-4 are attached to the common unit 20, but one of the wireless transmission / reception units 50-1 to 50-4 fails, the switching unit 31 performs the modulation / demodulation processing. Is switched to the other wireless transmission / reception units 50-1 to 50-4.

(4) Referring to FIG. 4B, a demultiplexing unit 33 is provided at the lowermost part of the common unit 20. When a signal of various frequency bands (channels) input from the antenna enters, the demultiplexing unit 33 divides the signal into signals of the respective frequency ranges and sends the signal to the radio transmitting / receiving units 50-1 to 50-4.

The electronic component package mounted on the common part 20 is inserted and removed (replaced) on the upper side of the common part 20. Therefore, the demultiplexer 33, which is rarely replaced, is provided at the bottom of the common unit 20.

The common unit 20 having the above-described internal structure controls the operations of the wireless transmission / reception units 50-1 to 50-4 in an integrated manner, and switches the wireless transmission / reception units 50-1 to 50-4 as necessary. And so on.

Next, the wireless transmission / reception units 50-1 to 50-4 will be described. Since each of the wireless transmission / reception units 50-1 to 50-4 has the same structure and operation, only the wireless transmission / reception unit 50-1 will be described below, and the other wireless transmission / reception units 50-2 to 50-4 will be described. The description of is omitted.

FIG. 5 is a diagram showing the appearance of the wireless transmission / reception unit 50-1, FIG. 5- (a) is a diagram viewed from the X2-X1 direction in FIG. 2, and FIG. 2 shows a view from the Y2-Y1 direction.

お よ び Referring to FIGS. 2 and 5, the wireless transmission / reception unit 50-1 is roughly composed of a wireless transmission / reception board 51 and a sunshade cover 52.

The electronic components mounted on the wireless transmission / reception board 51 are high heat generating components of, for example, about 50 W. Therefore, in order to prevent these electronic components from malfunctioning, the wireless transmission / reception board 51 is required to have effective heat radiation. In the present invention, the wireless transmission / reception unit 50-1 conventionally stored in the common unit is configured to be attached to the common unit 20 as a separate part from the common unit 20. That is, in the present invention, the wireless transmission / reception unit 50-1 is directly exposed to the outside air, and the electronic components are radiated to the outside air.

In addition, since the electronic components mounted on the common unit 20 do not generate high heat as compared with the electronic components mounted on the wireless transmitting and receiving panel 51, only the wireless transmitting and receiving units 50-1 to 50-4 are directly exposed to the outside air. What is necessary is just a structure.

A large number of radiating fins 57 are provided on the back member 54 of the wireless transmitting and receiving panel 51 vertically and horizontally as a radiating member. Heat from the microwave transmission unit 70 and the power supply unit 71 provided in the wireless transmission / reception board 51 described later is transmitted to the radiation fins 57 and radiated to the outside air. The heat dissipation structure will be described later.

As shown in FIG. 5- (a), a common section interface section 55 is provided substantially in the center below the back member 54 of the wireless transmitting / receiving section 50-1. As described above, the wireless transmission / reception units 50-1 to 50-4 are attached to the common unit 20, and the common unit interface unit 55 is fitted with the transmission / reception unit interface unit 24 of the common unit 20. The common unit interface unit 55 functions as an interface between the common unit 20 and the wireless transmission and reception unit 50 together with the transmission and reception unit interface unit 24 (see FIG. 2).

By the way, the height of the common portion interface portion 55 (the length in the X2-X1 direction in FIG. 2) is higher than the height of the radiation fins 57 (the length in the X2-X1 direction in FIG. 2). Therefore, when the wireless transmitting / receiving units 50-1 to 50-4 are attached to the common unit 20, a gap is formed between the right side unit 23 of the common unit 20 and the back member 54 of the wireless transmitting / receiving unit 50-1. . Therefore, air passes through this gap, and the heat radiation effect of the heat radiation fins 57 is improved.

面 Furthermore, a surface 55-1 made of aluminum or the like is provided at a portion higher than the radiation fins 57 of the common portion interface portion 55. When connecting the common unit interface unit 55 of the wireless transmitting / receiving unit 50-1 to the wireless transmitting / receiving unit interface unit 24 of the common unit 20, the surface 55-1 comes into contact with the wireless transmitting / receiving unit interface unit 24. A groove 55-2 is formed along the inner periphery of the surface 55-1. A waterproof packing 58 made of silicon rubber or the like is provided as a waterproof member in the groove 55-2.

Therefore, when the wireless transmission / reception unit 50-1 is attached to the common unit 20 and the common unit interface unit 55 is fitted to the transmission / reception unit interface unit 24 of the common unit 20, rainwater flows through the waterproof packing 58. 20 and the wireless transceiver 50-1 are prevented from entering. That is, with such a structure, while transmitting and receiving electricity and signals between the transmitting / receiving unit interface unit 24 of the common unit 20 and the common unit interface unit 55 of the wireless transmitting / receiving unit 50-1, the common unit 20 and the wireless transmitting / receiving unit The waterproof between the parts 50-1 is ensured.

The common unit interface unit 55 includes a first connector unit 100, a second connector unit 120, and a third connector unit 140 inside the surface 55-1. These structures will be described later.

Further, above the rear member 54 of the wireless transmission / reception board 51, a common part hook shaft member 56 is provided. Attachment of the wireless transmission / reception unit 50-1 to the common unit 20 is performed by hooking the common unit hook shaft member 56 on the transmission / reception unit bearing unit 25 of the common unit 20 and rotating the wireless transmission / reception unit 50-1. The wireless transmission / reception unit 50-1 is fixed to the common unit 20 in combination with the fitting of the unit interface unit 24 and the common unit interface unit 55. The structure for attaching the wireless transmitting / receiving unit 50-1 to the common unit 20 will be described later.

５− Referring to FIG. 5- (b), the wireless transmission / reception unit 50-1 is provided so as to be directly exposed to the outside air, but the wireless transmission / reception board 51 has a structure covered with a sunshade cover 52. The awning cover 52 shields the wireless transmission / reception board 51 from sunlight. A handle 53 is provided above the sunshade cover 52 for the convenience of the operator carrying the wireless transmission / reception unit 50-1.

Next, the internal structure of the wireless transmission / reception board 51 will be described. FIG. 6 is an exploded perspective view schematically showing the internal structure of the wireless transmission / reception board 51. Referring to FIG. 6, the wireless transmission / reception board 51 has a structure in which a waterproof housing 60 and a back member 54 provided with a large number of the radiation fins 57 described above are combined. In FIG. 6, only the position of the common section interface section 55 on the back member 54 is shown, and a detailed drawing of the structure is omitted.

The waterproof housing 60 has a recess 60-1 in the Y1-Y2 direction at the top of the X-Z surface. On the surface in the YZ direction of the waterproof housing 60, radiation fins 64 having a shape extending in the Z2 direction from the concave portion 60-1 are provided side by side in the Y1-Y2 direction.

On the back member 54, a first modulation / demodulation unit 61, a second modulation / demodulation unit 62, and a heat pipe casing 65 provided with a heat pipe 63 in parallel on the left and right sides (Y1-Y2 direction) of the upper surface are mounted.

ガ ス A gas such as chlorofluorocarbon flows inside the heat pipe 63. As will be described later, the heat pipe housing 65 covers electronic devices such as the microwave transmission unit 70, the power supply unit 71, and the microwave reception unit 72 mounted on the back member 54 (see FIG. 7).

As described above, each of the wireless transmission / reception boards 51 of the wireless transmission / reception units 50-1 to 50-4 includes an electronic device or the like in a superimposed manner, and each of the wireless transmission / reception boards 51 functions as one wireless transmission / reception device.

Next, the arrangement of the electronic devices provided on the back member 54 will be described in the order in which they are provided on the back member 54. FIG. 7 shows a state in which the microwave transmitting unit 70, the power supply unit 71, and the microwave receiving unit 72 are mounted on the surface of the back member 54 opposite to the surface on which the radiation fins 57 are provided. It is a perspective view. In FIG. 7, only the position of the common section interface section 55 on the back member 54 is shown, and a detailed drawing of the structure is omitted.

参照 Referring to FIG. 7, the microwave transmitting unit 70 is provided on the left side of the surface of the back member 54 opposite to the surface on which the heat radiation fins 57 are provided, and the power supply unit 71 is provided on the right side.

The microwave transmission unit 70 includes a housing in which high-frequency electronic components are disposed and the outside of which is made of aluminum. The microwave transmission unit 70 is in direct contact with the surface of the back member 54 opposite to the surface on which the heat radiation fins 57 are provided without any gap. Therefore, heat from the microwave transmission unit 70 is directly transmitted to the radiation fins 57 provided on the back member 54.

(4) The power supply unit 71 supplies power to the wireless transmission / reception board 51. The power supply unit 71 includes a printed circuit board 71-1, a power supply module 71-2 provided on the printed circuit board 71-1 and a printed circuit board on a surface of the back member 54 opposite to the surface on which the radiation fins 57 are provided. It is composed of a support leg 71-3 for supporting 71-1 and the like.

熱 A heat conductive sheet 71-4 is attached to the power supply module 71-2. Therefore, the power supply module 71-2 is in contact with the surface of the back member 54 opposite to the surface on which the heat radiation fins 57 are provided via the heat conductive sheet 71-4. Therefore, heat from the power supply module 71-2 is transmitted to the radiation fins provided on the back surface member 54. The reason why the heat conductive sheet 71-4 is used is that the surface of the printed board 71-1 and the back surface member 54 on which the radiation fins 57 are provided due to the warpage of the printed board 71-1. This is because the distance between the opposite surface may not be stable and is absorbed.

The microwave receiving section 72 includes a housing in which electronic components are disposed and the outside of which is made of aluminum. The microwave receiving unit 72 covers the microwave transmitting unit 70 and the power supply unit 71 described above, and is further provided on the surface opposite to the surface on which the heat radiation fins 57 of the back member 54 are provided by the four metal fittings 72-1. It is connected. A heat conductive sheet 72-2 is attached to the upper surface of the microwave receiving section 72. The heat conductive sheet 72-2 will be described later.

FIG. 8 is a perspective view showing a state in which a heat pipe housing 65 is further mounted on the back member 54 in the state shown in FIG. In FIG. 8, with respect to the common section interface section 55, only the position on the back member 54 is shown, and a detailed view of the structure is omitted. Is not shown in FIG.

参照 Referring to FIG. 8, a heat pipe housing 65 made of aluminum is mounted on the microwave receiving unit 72 (in the X1 direction in FIG. 6). In the vicinity of the four apex angles of the heat pipe housing 65, four support legs for supporting the heat pipe housing 65 on the surface opposite to the surface on which the radiation fins 57 of the back member 54 are provided. 65-1 are provided. Further, the heat pipes 63 are provided in parallel on the left and right sides (Y1-Y2 direction in FIG. 6) of the upper surface of the heat pipe housing 65, supported by a heat pipe support portion 65-2.

By the way, the above-described heat conductive sheet 72-2 (shown by a dotted line in FIG. 8) comes into contact with the heat pipe housing 65. Therefore, the heat from the microwave receiving unit 72 is transmitted to the heat pipe 63 provided on the upper surface of the heat pipe housing 65 via the heat conductive sheet 72-2 and the heat pipe housing 65.

FIG. 9 is a perspective view showing a state in which the first modem 61 is further mounted in the state shown in FIG. In FIG. 9, for convenience of description, the illustration of the microwave transmission unit 70, the power supply unit 71, the microwave reception unit 72, and the heat pipe support unit 65-2 illustrated in FIG. 8 is omitted.

参照 Referring to FIG. 9, the first modulation / demodulation unit 61 is mounted on the above-described heat pipe housing 65 (in the X1 direction in FIG. 6). Two support legs 61-3 for supporting the second modulator / demodulator 61 on the upper surface of the heat pipe casing 65 are provided in the vicinity of the two upper corners of the first modulator / demodulator 61. In the vicinity of the lower two apex portions, two support legs 61-4 for supporting the second modem 61 on the surface opposite to the surface on which the heat radiation fins 57 of the back member 54 are provided. Have been.

Further, a second modem connection connector 61-5 for connecting to a second modem 62, which will be described later, is provided substantially at the center below the upper surface of the printed circuit board 61-1 of the first modem 61. . A heat-generating component 61-2 (indicated by a dotted line in FIG. 9) is mounted on the surface of the printed circuit board 61-1 on the heat pipe housing 65 side.

FIG. 10 is a diagram illustrating the rear member 54, the heat pipe housing 65, and the first modulation / demodulation unit 61 illustrated in FIG. 9 when viewed from the Y2-Y1 direction in FIG. Referring to FIG. 10, a block 61-6 made of aluminum and a heat conductive sheet 61-7 are mounted on each heat generating component 61-2. The heat conductive sheet 61-7 is in contact with the heat pipe 63 provided on the upper surface of the heat pipe housing 65.

Therefore, the heat from the heat generating component 61-2 is transmitted to the heat pipe 63 via the block body 61-6 and the heat conductive sheet 61-7. The reason why the block body 61-6 and the heat conductive sheet 61-7 are used is that the distance between the printed board 61-1 and the heat pipe 63 is stable due to the warpage of the printed board 61-1. In some cases, it is not possible to absorb and adjust.

FIG. 11 is a diagram showing a state when the second modem unit 62 is attached to the first modem unit 61 shown in FIG. Referring to FIG. 11, four second modulation / demodulation section legs 62-1 are provided near the four apex angles of the printed circuit board 61-1 of the first modulation / demodulation section 61. The second modulation / demodulation unit 62 is mounted on the printed board 61-1 via the unit 62-1.

A first modulation / demodulation section connector 62-2 (dotted line in FIG. 11) for connecting to the first modulation / demodulation section 61 is provided substantially at the center below the surface of the second modulation / demodulation section 62 on the first modulation / demodulation section 61 side. ) Are provided. Therefore, when the second modulation / demodulation unit 62 is mounted on the first modulation / demodulation unit 61, the first modulation / demodulation unit connection connector 62-2 of the second modulation / demodulation unit 62 is connected to the second modulation / demodulation unit connection connector 61 of the first modulation / demodulation unit 61. Connect to -5.

発 熱 Furthermore, a heating component 62-4 is mounted on the upper surface of the printed circuit board 62-3 of the second modulation / demodulation unit 62. A heat conductive sheet 62-5 is attached to the heat generating component 62-4. As will be described later, when the second modulation / demodulation unit 62 is covered with the waterproof casing 60 (see FIG. 6), the heat-generating component 62-4 is dissipated through the heat conductive sheet 62-5. And heat is transmitted. The heat conductive sheet 62-5 is used because the distance between the printed board 62-3 and the radiating fins 64 may not be stable due to the warpage of the printed board 62-3, etc. This is for adjustment.

Next, the heat radiation structure of the wireless transmission / reception board 51 having the above-described internal structure will be described. FIG. 12 is a view for explaining the heat radiation structure of the wireless transmission and reception panel 51, and shows a cross-sectional view of the wireless transmission and reception panel 51 shown in FIG. 6 as viewed from the Y2-Y1 direction.

As described above, the wireless transmission / reception unit 50-1 including the wireless transmission / reception board 51 on which the electronic device with high power consumption is mounted is mounted on the common unit 20 so as to directly touch the outside air, Dissipates heat directly. Specifically, the wireless transmission / reception board 51 has a heat dissipation structure shown in FIG. 12 inside.

(4) The microwave transmitter 70 is in direct contact with the surface of the back member 54 opposite to the surface on which the heat radiation fins 57 are provided, without any gap. Therefore, the heat from the microwave transmission unit 70 is directly transmitted to the radiation fins 57 provided on the back member 54 and is radiated to the outside air.

As described with reference to FIG. 7, the power supply unit 71 is provided with the radiation fins 57 of the back member 54 via the heat conductive sheet 71-4 attached to the power supply module 71-2 of the power supply unit 71. Contacting the opposite side of the Therefore, the heat from the power supply module 71-2 is transmitted to the radiation fins provided on the back member 54, and is radiated to the outside air.

Heat from the microwave receiving unit 72 is transmitted via a heat conductive sheet 72-2 attached to the upper surface of the microwave receiving unit 72 and a heat pipe housing 65 made of aluminum in contact with the heat conductive sheet 72-2. Can be transmitted to the heat pipe 63 provided on the upper surface of the heat pipe housing 65.

The heat from the heat-generating component 61-2 mounted on the printed circuit board 61-1 of the first modulation / demodulation unit 61 is transmitted through the block 61-6 and the heat conductive sheet 61-7 on the heat-generating component 61-2. The information is transmitted to the pipe 63.

The heat pipe 63 is in contact with the concave portion 60-1 of the waterproof housing 60 via the heat dissipation sheet 80. Therefore, the heat transmitted to the heat pipe 63 is radiated to the outside air.

(4) The heat from the heat-generating component 62-4 mounted on the printed circuit board 62-3 of the second modulation / demodulation unit 62 is transmitted to the waterproof housing 60 via the heat conductive sheet 62-5, and is radiated to the outside air. The height (the length in the left-right direction in FIG. 12) of the heat-generating component 62-4 differs depending on each component. Therefore, with respect to the heat generating component 62-4 having a low height, the convex portion 60-9 is provided on the waterproof housing 60, and together with the heat conductive sheet 62-5, the difference in the height is absorbed, and the printing is performed. The distance between the substrate 62-3 and the waterproof housing 60 is stabilized.

By the way, since the radiation fins 64 of the waterproof housing 60 are used by being covered with the sunshade cover 52 (see FIG. 5), only the Z1-Z2 direction in FIG. Good. Therefore, the radiation fins 64 are provided at substantially equal intervals in the Y1-Y2 direction in FIG.

On the other hand, the heat radiation fins 57 of the back member 54 have slits on the way in the Y1-Y2 direction described above, so that the flow of the wind contributing to heat radiation is improved and the heat radiation effect is further enhanced.

In the wireless transmission / reception board 51 having the above-described structure, although electronic devices are mounted at high density inside, heat from each electronic device is efficiently radiated to the outside air.

Next, the processing and flow of the radio frequency via the microwave receiving unit 72 or the microwave transmitting unit 70, the first modem 61 and the second modem 62 will be described.

The radio frequency having a frequency of, for example, 18 GHz input to the common unit 20 via the antenna is distributed by the common unit 20, and is transmitted and received via the transmission / reception unit interface unit 24 and the common unit interface unit 55. Sent to The frequency is converted to a frequency of, for example, 844 MHz by the microwave local signal in the microwave receiving unit 72. Next, the frequency converted by the microwave receiving unit 72 is converted into a frequency of, for example, 70 MHz by the first modulation / demodulation unit 61 by a local signal. Further, the frequency converted by the first modulation / demodulation unit 61 is converted into a frequency of, for example, 28 MHz by a local signal in the second modulation / demodulation unit 62, demodulated to a signal of, for example, 155 Mbps, and sent to the common unit 20. The signal is switched by the common unit 20 and taken into an external device connected to the external connector 27.

When transmitting radio frequencies, the procedure is the reverse of the above-mentioned case. That is, the signal of, for example, 155 Mbps sent from the external device to the common unit 20 is switched by the common unit 20 and sent to the wireless transmitting / receiving unit 50-1. The signal transmitted to the second modulation / demodulation unit 62 of the wireless transmission / reception unit 50-1 is modulated to a frequency of, for example, 28 MHz, and further converted to, for example, 70 MHz by a local signal. The frequency switched by the second modulation / demodulation unit 62 is converted into, for example, 844 MHz by the first modulation / demodulation unit 61 by a local signal. Next, the frequency converted in the first modulation / demodulation unit 61 is converted into a frequency of 18 GHz by a microwave local signal in a microwave transmission unit 70, and transmitted via the transmission / reception unit interface unit 24 and the common unit interface unit 55. And sent to the common unit 20. The radio frequency transmitted to the common unit 20 is transmitted via an antenna.

Next, a description will be given of a fitting structure between the transmission / reception unit interface unit 24 of the common unit 20 and the common unit interface unit 55 of the wireless transmission / reception unit 50-1.

FIG. 13 is a diagram showing details of the structure of the common unit interface unit 55 of the wireless transmitting / receiving unit 50-1. More specifically, FIG. 13A shows a state in which the sunshade cover 52, the waterproof housing 60, and predetermined electronic components have been removed from the wireless transmitting and receiving unit 50-1 in the state shown in FIG. FIG. 7 is a diagram of the wireless transmission / reception unit 50-1 viewed from a Y2-Y1 direction in FIG. In FIG. 13A, the internal structure of the common unit interface unit 55 is seen through. FIG. 13- (b) is a diagram of the wireless transmission / reception unit 50-1 in the state shown in FIG. 13- (a) viewed from the direction A in FIG. 13- (a).

5 and 13, the common unit interface unit 55 of the wireless transmission / reception unit 50-1 includes a first connector unit 100, a second connector unit 120, and a third connector unit 140.

The first connector section 100 transmits and receives electricity and signals to and from the transmission / reception section interface section 24 of the common section 20. About 200 pins are provided in the first connector fitting portion 100-1. The first connector fitting section 100-1 is connected to the second modulation / demodulation section 62 via a printed board and wiring (not shown). Guide pin receiving holes 100-2 are provided on the left and right of the first connector fitting portion 100-1.

As shown in FIG. 13B, both ends of the first connector portion 100 are attached to the fixing plate 210 by two fixing screws 200.

14A and 14B are schematic views showing the structure of the first connector section 100, FIG. 14A is a perspective view of the first connector section 100, and FIG. 14 (a) is a view of the first connector portion 100 shown in FIG. 14- (a) viewed from the direction A. FIG. 14- (c) shows the first connector portion 100 shown in FIG. It is the figure seen from B direction in a).

Referring to FIG. 14, the first connector portion 100 includes a screw receiving portion 101 for receiving a fixing screw 200 at both ends. The screw receiving portion 101 has a hollow hole 101-1 substantially at the center. The fixing screw 200 is inserted into the hollow hole 101-1 and screwed, and the first connector portion 100 is attached to the fixing plate 210.

FIG. 15 is a schematic diagram showing the relationship between the fixing screw 200, the screw receiving portion 101 of the first connector portion 100, and the fixing plate 210. More specifically, FIG. 15A is a schematic diagram illustrating a dimensional relationship between the fixing screw 200, the screw receiving portion 101, and the fixing plate 210, and FIG. FIG. 4 is a schematic view showing a case where the screw receiving portion 101 is attached to a fixing plate 210.

固定 Referring to FIG. 15- (a), the fixing screw 200 includes a first shaft 200-1, a second shaft 200-2, and a head 200-3. A thread groove is formed in the first shaft portion 200-1. The diameter B of the second shaft portion 200-2 is larger than the diameter of the first shaft portion 200-1, but smaller than the diameter A of the hollow hole 101-1 of the screw receiving portion 101. Further, the axial length D of the second shaft portion 200-2 is longer than the axial length C of the hollow hole 101-1 of the screw receiving portion 101.

Therefore, as shown in FIG. 15B, even if the first shaft portion 200-1 of the fixing screw 200 is locked to the fixing plate 210, the screw receiving portion 101 of the first connector portion 100 and the second shaft portion 200-1 are locked. A floating structure is formed such that a gap is formed between the portion 200-2. Since the first connector section 100 has the above-described floating structure, the wireless transmission / reception section 50-1 has a play that can be moved up and down, left and right, that is, freely floating.

Therefore, the guide pin 300-2 provided in the first connector part 300 of the transmission / reception part interface part 24 of the common part 20 shown in FIG. 3 is guided by the guide pin receiving hole 100-2, and the transmission / reception part interface is provided. When the first connector fitting portion 300-1 of the portion 24 is fitted with the first connector fitting portion 100-1 of the common portion interface portion 55, positioning can be performed with a degree of freedom.

Next, a description will be given of a fitting structure of the second connector section 120 of the common section interface section 55 of the wireless transmitting / receiving section 50-1 and the second connector section 320 of the transmitting / receiving section interface section 24 of the common section 20.

FIG. 16 is a schematic view showing a side cross section of the second connector section 320 of the transmission / reception section interface section 24 of the common section 20 shown in FIG.

に Referring to FIG. 16, the second connector section 320 is generally constituted by an outer shell 320-1 and an inner shell 320-2. The outer shell 320-1 houses an inner shell 320-2 and an elastic member 320-3 such as a spring provided around the inner shell 320-2. A conductor member 320-4 is provided substantially at the center of the inside of the inner shell 320-2. A retaining ring 320-5 that supports the inner shell 320-2 is provided around the inner shell 320-2 and behind the outer shell 320-1.

13, among the second connector sections 120 of the common section interface section 55 of the wireless transmitting / receiving section 50-1, the second connector section 120 on the left side in FIG. It is connected to the microwave transmitter 70. Further, as shown in FIG. 13, the second connector section 120 on the right side in FIG. 13 is connected to the microwave receiving section 72 via the pipe cable 410. Further, the second connector section 120 projects vertically in the paper of FIG. 5A, and is inserted into the inner shell 320-2 of the second connector section 320 of the transmitting / receiving section interface section 24 of the common section 20. Can be.

弾 性 As described above, the elastic member 320-3 is provided around the inner shell 320-2. Therefore, when the second connector section 120 of the wireless transmitting / receiving section 50-1 is inserted into the inner shell 320-2 of the second connector section 320 of the common section 20, the second connector section 120 of the wireless transmitting / receiving section 50-1 is In addition, a floating structure is formed that can move up and down, left and right, that is, can freely float together with the inner shell 320-2 of the second connector section 320 of the common section 20.

Therefore, when attaching the second connector section 120 of the wireless transmission / reception section 50-1 to the second connector section 320 of the common section 20 under the above-described floating structure, the second connector section 120 is fitted with a degree of freedom even if there is a step error. it can.

Signals are transmitted and received between the second connector section 120 of the common section interface section 55 of the wireless transmitting / receiving section 50-1 and the second connector section 320 of the transmitting / receiving section interface section 24 of the common section 20.

Next, a description will be given of a fitting structure of the third connector section 140 of the common section interface section 55 of the wireless transmitting / receiving section 50-1 and the third connector section 340 of the transmitting / receiving section interface section 24 of the common section 20.

Referring to FIGS. 5- (a) and 13- (b), the third connector section 140 of the common section interface section 55 of the wireless transmission / reception section 50-1 is configured as shown in FIGS. 5- (a) and 13- ( It protrudes vertically on the paper surface of b) and can be inserted into the third connector portion 340 of the transmission / reception portion interface portion 24 of the common portion 20.

As shown in FIG. 3, attachment portions 360 for attaching the third connector portion 340 to the transmission / reception unit interface unit 24 are provided on the left and right of the third connector unit 340 of the transmission / reception unit interface unit 24 of the common unit 20. Is provided.

FIG. 17 is a diagram schematically illustrating a state in which the third connector section 340 is attached to the transmitting / receiving section interface section 24 using the attaching section 360. More specifically, FIG. 17- (a) is an exploded perspective view of the third connector section 340, the mounting section 360, and the interface section 24 for the transmitting / receiving section, and FIG. 17- (b) is an exploded perspective view. FIG. 7A is a diagram showing a state in which the mounting section 360 shown in FIG. 6A is mounted on the transmitting / receiving section interface section 24 of the common section 20 by using a mounting screw 360-3.

Referring to FIG. 17, the mounting portion 360 is provided with a mounting hole 360-1 having a substantially central hollow portion. Further, a bush member 360-2 having a substantially central hollow is inserted into the mounting hole 360-1. A head 360-2a is provided at both ends of the bush member 360-2, and a shaft 360-2b is provided between both ends.

直径 The diameter F of the shaft 360-2b of the bush member 360-2 is larger than the diameter of the head 360-2a, but smaller than the diameter E of the mounting hole 360-1. The axial length G of the shaft portion 360-2b is longer than the length H of the mounting hole 360-1. Therefore, as shown in FIG. 17- (b), even if the mounting screw 360-3 is mounted on the transmitting / receiving section interface section 24 through the mounting section 360, the mounting hole 360- of the bush member 360-2 and the mounting section 360 is provided. 1, a floating structure is formed in which the bush member 360-2 can move freely in the gap.

That is, the third connector section 340 of the transmitting / receiving section interface section 24 of the common section 20 has a play that can be moved up, down, left, and right. Therefore, when the third connector 140 of the common interface 55 of the wireless transmitting / receiving unit 50-1 is attached to the third connector 340 of the transmitting / receiving interface 24 of the common unit 20 under the above-described floating structure, Even if there is a step error, it can be fitted with a degree of freedom.

The third connector section 140 of the common section interface section 55 of the wireless transmission / reception section 50-1 is connected to the first modulation / demodulation section 61 via a cable (not shown).

Under the above structure, transmission and reception of signals between the third connector section 140 of the common section interface section 55 of the wireless transmitting / receiving section 50-1 and the third connector section 340 of the transmitting / receiving section interface section 24 of the common section 20 are performed. Is performed.

As described above, since the interface unit 55 for the common unit of the wireless transmitting / receiving unit 50-1 and the interface unit 24 for the transmitting / receiving unit of the common unit 20 have the above-described floating structure, it is assumed that one or both of them has a step error or the like. Also, the two can be securely fitted, and the wireless transmitting / receiving unit 50-1 can be electrically connected to the common unit 20.

Next, the mounting structure of the wireless transmitting / receiving unit 50-1 to the common unit 20 will be described. FIG. 18 is a diagram for explaining a structure of attaching the wireless transmitting / receiving unit 50-1 to the common unit 20. FIG. 18 illustrates a state in which the common unit 20 of the wireless transmitting / receiving unit 50-1 is attached in the Y2-Y1 direction in FIG. FIG.

Referring to FIG. 18, the common unit hooking shaft member 56 provided above the back member 54 of the wireless transmitting / receiving unit 50-1 is attached to the transmitting / receiving unit bearing unit 25 provided above the right side surface 23 of the common unit 20. , The wireless transmission / reception unit 50-1 is rotated in the direction indicated by the arrow in FIG. Above the wireless transmission / reception unit 50-1 and above the common unit 20, the common unit hook shaft member 56 is received and fixed by the transmission / reception unit bearing unit 25. On the other hand, the lower part of the wireless transmission / reception unit 50-1 and the lower part of the common unit 20 are fixed by fitting the transmission / reception unit interface unit 24 and the common unit interface unit 55 described above. In this way, the wireless transmission / reception units 50-1 to 50-4 are attached to the common unit 20 and fixed.

By the way, as described above, the height of the common portion interface portion 55 (the length in the X2-X1 direction in FIG. 2) is greater than the height of the radiation fins 57 (the length in the X2-X1 direction in FIG. 2). Is getting higher. Therefore, when the wireless transmission / reception unit 50-1 is attached to the common unit 20, a gap is formed between the radiation fin 57 and the right side surface unit 23 of the common unit 20. Therefore, air can enter the gap, and heat radiation from the radiation fins 57 of the wireless transmitting and receiving unit 50-1 to the outside air is promoted.

Further, as described above, the groove 55-2 is formed along the inner periphery of the surface 55-1 on the surface 55-1 of the portion higher than the radiation fins 57 of the common unit interface 55, and the groove 55-2 is formed. A waterproof packing 58 is provided in one part as a waterproof member (see FIG. 5). Therefore, as described above, when the wireless transmitting / receiving unit 50-1 is attached to the common unit 20 and the common unit interface unit 55 is fitted to the transmitting / receiving unit interface unit 24, the waterproof packing 58 is attached to the wireless transmitting / receiving unit 50. -1 is in close contact with the common unit interface 55. Therefore, it is possible to prevent rainwater from entering the common unit 20 and the wireless transmission / reception unit 50-1. In this way, even when the wireless transmitting / receiving units 50-1 to 50-4 and the common unit 20 are installed outdoors, the waterproofness of the electronic device mounted inside is ensured.

With the above-described mounting structure, the wireless transmitting / receiving unit 50-1 can be easily mounted outside the common unit 20. Since the wireless transmission / reception units 50-1 to 50-4 are provided outside the common unit 20, one wireless transmission / reception unit is used as one exchange unit (addition unit) depending on the usage mode, and the other wireless transmission / reception units are used. When adding 50-2 to 50-4, or for maintenance or the like of each of the wireless transmission / reception units 50-1 to 50-4, the respective wireless transmission / reception units 50-1 to 50-4 are removed from the common unit 20 and replaced. In this case, the work can be easily performed.

For example, the configuration of the demultiplexing unit 33 is appropriately changed, and the number of the wireless transmission / reception units 50-1 to 50-4 to be attached to the common unit 20 is changed so that the single polarization (for example, only V polarization) or the dual polarization (V / H polarization), one of the wireless transmission / reception units 50-1 to 50-4 is used for standby or standby, and the remaining (1 to 3 units) are actually used. 50-1 to 50-4 can be used. Note that it is not always necessary to provide a standby or standby wireless transmission / reception unit, and a configuration may be employed in which up to four wireless transmission / reception units 50-1 to 50-4 are actually used.

Further, with the above-described structure, transmission and reception of electricity and signals between the transmission / reception unit interface unit 24 of the common unit 20 and the common unit interface unit 55 of the radio transmission / reception unit 50-1 are performed, −1, and at the same time, waterproofing between the common unit 20 and the wireless transmitting / receiving unit 50-1 is ensured.

Although the preferred embodiment of the present invention has been described in detail, the present invention is not limited to the specific embodiment, and various modifications and changes may be made within the scope of the present invention described in the appended claims. Changes are possible.

FIG. 19 is a block diagram showing a reference example of a wireless device for outdoor installation having a one-channel configuration. This device is constructed integrally with transmission and reception, and includes a transmission main signal circuit 81, a reception main signal circuit 82, a transmission local oscillator 83, a reception local oscillator 84, a reference signal generation unit 85, a transmission control unit 86, a reception control unit 87, It comprises an indoor device communication unit 88.

In the transmission system operation, the transmission main signal circuit 81 converts the frequency of the transmission signal S1 transmitted from the indoor unit into a radio frequency by the transmission local oscillation signal supplied from the transmission local oscillator 83, and further controls the transmission output level. , And outputs a transmission radio signal S2.

In the reception system operation, the received radio signal S3 is frequency-converted to an intermediate frequency by the reception local oscillation signal generated by the reception local oscillator 84 in the reception main signal circuit 82, further subjected to AGC amplification, and then to the indoor unit. Is output.

The transmission system control unit 86 performs transmission output level control and transmission monitor control, and the reception system control unit 87 performs AGC amplification and reception monitor control. The indoor device communication unit 88 performs communication for transmitting transmission / reception monitor information and the like obtained by the transmission system control unit 86 and the reception system control unit 87 to the indoor device 89.

FIG. 20 is a block diagram of a reference example of a wireless device for outdoor installation having a four-channel configuration. In the figure, outdoor wireless units 91 to 94 correspond to the wireless transmitting and receiving units 50-1 to 50-4 shown in FIG. 2, and the outdoor common unit 95 corresponds to the common unit 20 shown in FIG. The common section 20 is provided with band-pass filters 96a to 96h.

The outdoor wireless units 91 to 94 each perform the operation of the outdoor installation wireless device in FIG. 19, and transmit signals S1, S3, S5, and S7 transmitted from the indoor device 97 to the outdoor wireless units 91 to 94 on the transmission side. The frequency is converted into a radio frequency by a local oscillation signal generated by each of the local oscillators 98, the transmission output level is controlled, and the bandpass filters 96a to 96d in the outdoor common use unit 5 perform filtering, and then transmit. The wireless signals S2, S4, S6, and S8 are output.

On the receiving side, the radio reception signals S9, S11, S13, and S15 are filtered by the band-pass filters 96e to 96h of the outdoor common use unit 95, and the outdoor radio units 91 to 94 convert the frequency to an intermediate frequency by the local oscillator 98. Further, AGC amplification is performed, and received signals S10, S12, S14, and S16 are output to the indoor unit 97. The transmission / reception monitor information of each outdoor wireless unit obtained from the transmission / reception system control units of the outdoor wireless units 91 to 94 is transmitted to the indoor device 97 by each indoor communication unit 99.

FIG. 21 is a configuration diagram of a reference example of the local oscillator 98. In the figure, a PLLIC (Phase Locked Loop Integrated Circuit) 106 and a VCO (Voltage Controlled Oscillator) 107 in the first stage operate based on a signal obtained from a reference oscillator 105 to generate a reference signal for a transmission system. The PLLIC 108 generates a reference signal for the receiving system based on output signals of the transmitting PLLIC 106 and the VCO 107. The reason why the reference signal is not directly used is to protect the rear PLLICs 111, 113, 115, and 117 from being changed with respect to a phase change when the reference signal is switched or the like.

Furthermore, two PLLICs are provided for transmission and reception because the transmission frequency and the reception frequency are separated by about 1 GHz, so that frequency accuracy can be easily obtained for each channel. The PLLICs 111 and 113 are used to obtain a frequency on the transmission side. The PLLIC 111 performs rough frequency setting, and the PLLIC 113 performs fine frequency setting. The final frequency of the transmission system local oscillator is determined by the combination of the PLLICs 111 and 113.

The PLLICs 115 and 117 are used to obtain the frequency of the receiving system. The PLLIC 115 performs rough frequency setting, and the PLLIC 117 performs fine frequency setting. The combination of the PLLICs 115 and 117 determines the final frequency of the local oscillator in the receiving system.

Here, the reference oscillator 105, the PLLICs 106 and 108, and the VCOs 107 and 109 are the same reference frequency generator 121 having the same frequency band and the same setting, and the PLLICs 111, 113, 115 and 117, and the VCOs 112, 114, 116 and 118 are set with the same frequency channel. Are the same channel setting unit 122.

FIG. 22 is a configuration diagram of a four-channel local oscillator using the local oscillator 98. In this case, since the channel frequency is different in each outdoor radio unit, the local oscillator 98 is divided for each outdoor radio unit.

FIG. 23 shows a configuration diagram of a local oscillator having a two-channel co-channel configuration using the local oscillator 98. The outdoor radio units 91 and 92 allocate the same channel 1 frequency, and the outdoor radio units 93 and 94 allocate the same channel 2 frequency. The channels 1 and 2 have the same frequency, but the radio can propagate the horizontal polarization and the vertical polarization differently. In order to realize this, synchronization has to be established between the outdoor wireless units, each serving as a common channel, and it is necessary to share a reference signal. Therefore, a reference signal interface for transferring a reference signal is provided between the reference generators 121 of the outdoor wireless units 91 and 92 and between the reference generators 121 of the outdoor wireless units 93 and 94. Normally, both reference signals are transferred due to a problem at the time of start-up, and the operation is performed such that the power supply of the apparatus is used first as a reference.

By the way, the following problems arise when configuring an outdoor installation wireless device having a plurality of channels. Since the reference generator 121 is provided for each channel, a highly stable reference oscillator 105 is required for each channel, and the cost of the reference generator 121 increases as the number of systems increases. In addition, when a co-channel is configured, a reference signal interface is required for each same frequency channel, and the number of interfaces such as cable connections increases.

Each of the outdoor wireless units 91 to 94 has a plurality of identical circuits such as a reference signal generating unit 85, a transmission control unit 86, and a reception control unit 87. In the case of adding a system, one wireless device having all functions is provided. The unit must be mounted as it is, and the setting of the radio frequency cannot be easily changed.

シ ス テ ム In the construction of a system such as a co-channel, it is necessary to synchronize the reference between the systems, and a plurality of interfaces are generated between the individual systems. Each of the outdoor wireless units 91 to 94 requires an indoor communication unit 99 for communicating with the indoor device 95.

In order to solve the above problem, the present invention has the following configuration. A band configuration unit is not provided for each channel, and one circuit is used for the entire wireless device. The local oscillators present in each outdoor radio unit are integrated into one circuit and mounted in the system common unit. The processing of the transmission control unit and the reception control unit existing in each outdoor wireless unit is realized by time-division processing, and is integrated and mounted in a common part. A common unit including a radio unit on which a radio main signal is mounted, a local oscillator, and a control unit is physically divided, and a plurality of outdoor radio units are separately mounted on one common unit. The frequency of the radio channel is determined, and a band-pass filter provided at the transmission output or the reception input is mounted on the outdoor radio unit.

FIG. 24 is a block diagram showing a four-channel wireless device for outdoor installation according to the present invention. In the figure, outdoor wireless units 131 to 134 correspond to the wireless transmitting / receiving units 50-1 to 50-4 shown in FIG. 2, and the outdoor common unit 135 corresponds to the common unit 20 shown in FIG. The outdoor common use unit 135 includes a communication control unit 136 including a transmission control unit, a reception control unit, and an indoor communication unit, and a reference signal generation unit 137 including a frequency setting unit.

On the transmitting side of the outdoor wireless units 131 to 134, the transmission signals S 1, S 3, S 5, and S 7 transmitted from the indoor unit 138 by the transmission main signal unit 141 are converted to respective radio frequencies using the local oscillation signal from the PLL circuit 142. After performing frequency conversion, performing transmission output level control and performing filtering with a band-pass filter (BR-FIL) 143, the transmission radio signals S2, S4, S6, and S8 are output.

On the reception side, the radio reception signals S9, S11, S13, and S15 are filtered by the respective band-pass filters 144, and the reception main signal unit 145 converts the frequency to an intermediate frequency signal using the signal from the PLL circuit 142. After further performing AGC amplification, reception signals S10, S12, S14, and S16 are output to indoor unit 138.

The outdoor common unit 135 is an interface between the outdoor wireless units 131 to 134 and the indoor device 138, and includes a communication control unit 136 and a reference signal generating unit 137 shared by the outdoor wireless units 131 to 134. By attaching and detaching the outdoor wireless units 131 to 134 to and from the outdoor common unit 135, the number of wireless channels is increased or decreased.

The communication control unit 136 performs transmission / reception main signal control of all of the outdoor wireless units 131 to 134 by time division multiplexing, and performs time division multiplexing of transmission / reception monitors obtained from all of the outdoor wireless units 131 to 134 to the indoor unit 138. Communicate to The reference signal generator 137 transmits the reference signal of the PLL circuit 142 to all of the outdoor wireless units 131 to 134, and the outdoor wireless units 131 to 134 perform frequency conversion based on this signal.

FIG. 25 shows a configuration diagram of a local oscillator in a four-channel configuration and a two-channel co-channel configuration in the present invention. The reference signal generator 137 arranged in the outdoor common unit 135 corresponds to the reference generator 121 shown in FIG. 21 and generates and outputs a reference signal. PLL circuits 142 arranged in each of the outdoor wireless units 131 to 134 correspond to the channel setting unit 122 shown in FIG. 21, and transmit and receive local oscillation of each channel in synchronization with a reference signal commonly supplied from the reference signal generating unit 137. Generate a signal. In a four-channel configuration, the PLL circuits 142 of the outdoor radio units 131 to 134 are assigned to channels 1 to 4. In a two-channel co-channel configuration, the PLL circuits 142 of the outdoor radio units 131 and 132 use the channel 1 for the outdoor radio units. The PLL circuits 142 of 133 and 134 are assigned to the channel 2.

時 With reference to FIG. 26, a description will be given of time division multiplexing control in a four-channel configuration according to the present invention. FIG. 26A shows the outdoor wireless units 131 to 134 and the outdoor common unit 135. FIG. 26- (b) shows a hardware configuration of an outdoor wireless unit for one channel. The outdoor wireless section is incorporated in the transmission main signal section 141, the PLL circuit 142, the transmission output detection circuit 148, the transmission output variable circuit 149 incorporated in the transmission main signal section 141, the reception main signal section 145, and the reception main signal section 145. And a receiving output detection circuit 152.

FIG. 26- (c) shows the hardware configuration of the outdoor common use unit 135. The outdoor common use unit 135 includes a communication control unit 136 and a reference signal generation unit 137. The communication control unit 136 includes an A / D converter 155, a CPU 156, and a D / A converter 157, and the reference signal generation unit 137 includes a reference signal oscillator 158 and a distributor 159.

On the transmission side, the transmission input signal T-in is frequency-converted by the transmission main signal unit 141, the level is detected by the transmission output detection circuit 148, and the transmission output detection signal T-det is output to the outdoor common unit 135. The signal is converted into a digital signal by the A / D converter 155 of the communication control unit 136 and input to the CPU 156.

The CPU 156 performs a transmission monitoring process and an alarm process based on this signal, generates a transmission output control voltage T-ctrl, converts the T-ctrl into an analog signal by the D / A converter 157, and outputs the voltage to the transmission output variable circuit 149. By supplying, the level control of the transmission output signal T-out is performed.

On the transmitting side, after the received input signal R-in input to the receiving main signal section 145 is frequency-converted, the level is detected by the receiving output detection circuit 152, and the transmission output detection signal R-det is sent to the outdoor common use section 135. After being output and converted into a digital signal by the A / D converter 155 of the communication control unit 136, the CPU 156 performs transmission monitoring processing and alarm processing.

(4) In the reference signal generator 137 of the outdoor common unit 135, the output of the reference signal oscillator 158 is distributed and output to each outdoor wireless unit as a reference signal Reference by the distributor 159. The PLL circuit 142 of each outdoor wireless unit generates a local signal for frequency conversion based on the reference signal Reference and the oscillator setting data PLL-data output from the CPU 156. The outdoor common unit 135 performs a series of these controls on all outdoor wireless devices by time division multiplexing.

FIG. 27 is an explanatory diagram of 4-channel time division multiplexing control. After turning on the power, the communication control unit 136 of the outdoor sharing unit 135 transmits the oscillator setting data PLL-data to the PLL circuit 142 of each outdoor wireless unit in order from channel 1 and determines the frequencies of all the outdoor wireless units. Transmission detection signals are input in order from channel 1 to channel 4, transmission monitoring / alarm processing is performed, and transmission control signals are generated. Thereafter, a reception detection signal is input, and reception monitoring and alarm processing are performed. Then, in the communication processing, the transmission output control signals of all the channels are collectively communicated to the outdoor wireless units 131 to 134, and the transmission / reception monitor / alarm signals of all the channels are collectively communicated to the indoor unit 138. After the communication is completed, the above processing is repeatedly executed from the transmission control of channel 1. The processing time of each channel is performed within a fixed time t, thereby making the processing time of each of the outdoor wireless units 131 to 134 uniform.

FIG. 28 is a schematic diagram of an outdoor wireless device of the space diversity combining and receiving system. Here, one transmission unit and two reception units are integrally formed. In the figure, an outdoor wireless device 160 includes a transmission main signal circuit 161, a main-side reception main signal circuit 162, an SD (Space Diversity) -side reception main signal circuit 163, an in-phase synthesis circuit 164, a common unit 165, a main-side antenna 166, It is composed of an SD-side antenna 167.

In the transmission system, the transmission signal S1 transmitted from the indoor device 168 is output as the transmission radio signal S2 from the main antenna 166 via the transmission main signal circuit 161. In the receiving system, the radio signal S3 received by the main-side antenna 166 is supplied to the in-phase combining circuit 164 via the main-side receiving main signal circuit 162.

{Circle around (4)} The radio signal S4 received by the SD antenna 167 installed at a position distant from the main antenna 166 is input to the in-phase combining circuit 164 via the SD receiving main signal circuit 163. The in-phase combining circuit 164 performs in-phase combining of the wireless signals S3 and S4, and outputs a combined signal S5 to the indoor unit 168.

FIG. 29 is a block diagram of a wireless device for outdoor installation in a space diversity type 4-channel configuration according to the present invention. In the figure, outdoor wireless units 171 to 174 correspond to the wireless transmitting / receiving units 50-1 to 50-4 shown in FIG. 2, and the outdoor common unit 175 corresponds to the common unit 20 shown in FIG. The outdoor common use unit 175 is provided with a communication control unit 176 including a transmission control unit, a reception control unit, and an indoor communication unit, and a reference signal generation unit 177 including a frequency setting unit. 178 is an indoor device, 179 is a main antenna, and 180 is an SD antenna.

On the transmitting side of the outdoor wireless units 171 to 174, the transmission signals S1, S3, S5, and S7 transmitted from the indoor unit 178 by the transmission main signal unit 181 are frequency-converted to radio frequencies by local oscillation signals from the respective PLL circuits 182. Then, after performing transmission output level control and filtering by the band-pass filter 183, the transmission radio signals S2, S4, S6, and S8 are output.

On the main reception side, the radio reception signals S9, S11, S13, and S15 are filtered by the band-pass filter 184, and the reception main signal section 185 converts the frequency to an intermediate frequency signal by the local oscillation signal from the PLL circuit 182, and then performs in-phase. The signal is supplied to the synthesizer 186.

On the SD receiving side, the radio reception signals S17, S18, S19, and S20 are filtered by the band-pass filter 187, and the reception main signal section 188 converts the frequency to an intermediate frequency signal by the local oscillation signal supplied from the infinite phase shifter 189. Thereafter, the signal is supplied to the in-phase combiner 186 through the delay adjuster 190.

(4) The in-phase combiner 186 performs AGC amplification and outputs received signals S10, S12, S14, and S16 to the indoor unit 178. The outdoor common unit 175 is an interface unit between the outdoor wireless units 171 to 174 and the indoor device 178, and includes a communication control unit 176 and a reference signal generating unit 177 shared by the outdoor wireless units 171 to 174. The number of wireless channels is increased or decreased by attaching or detaching 171 to 174.

The communication control unit 176 controls all transmission / reception main signals of the outdoor radio units 171 to 174 by time division multiplexing, and transmits / receives the transmission / reception monitors obtained from all the outdoor radio units 171 to 174 to the indoor unit 178 by time division multiplexing. introduce. The reference signal generation unit 177 transmits the reference signal of the PLL circuit 182 to all of the outdoor wireless units 171 to 174, and each outdoor wireless unit performs frequency conversion based on this signal.

The control of the infinite phase shifter will be described with reference to FIGS. FIG. 30 shows the entire wireless device for outdoor installation, and the connection between the communication control unit 176 and the reference signal generating unit 177 and the outdoor wireless units 171 to 174 is omitted. FIG. 31 shows infinite phase shift control in the outdoor radio section for one channel. In both figures, the infinite phase shifter control section 191 of the outdoor common use section 175 includes an intermediate frequency signal on the main reception side transmitted from the phase difference detection circuit 192 incorporated in the in-phase combiner 186 of the outdoor radio sections 171 to 174 and the SD. Phase difference information with the intermediate frequency signal on the receiving side is received by time division multiplexing. An infinite phase shifter control signal is generated based on this phase difference information, and transmitted to the infinite phase shifters 189 of the outdoor wireless units 171 to 174 by time division multiplexing.

Accordingly, each infinite phase shifter 189 is controlled so as to cancel the phase shift difference between the main-side intermediate frequency signal and the SD-side intermediate frequency signal. With this control, the main-side intermediate frequency signal and the SD-side intermediate frequency signal are in-phase synthesized by the in-phase synthesizer.

The control of the delay adjuster will be described with reference to FIG. FIG. 32 shows the entirety of the wireless device for outdoor installation, and the connection between the communication control unit 176 and the reference signal generating unit 177 and the outdoor wireless units 171 to 174 is omitted. In the figure, the variable delay control section 192 of the outdoor common use section 175 transmits a delay control signal to all the delay adjusters 190 of the outdoor wireless sections 171 to 174 by time division multiplexing according to the setting information from the indoor apparatus 178.

By this control, the delay time (fixed) corresponding to the difference between the delay time from the main antenna 179 to each of the outdoor radio units 171 to 174 and the delay time from the SD antenna 180 to each of the outdoor radio units 171 to 174 is delayed. The adjustment is performed by the adjuster 190 so that the delay time from the main antenna 179 to the in-phase combiner 186 and the delay time from the SD antenna 180 to the in-phase combiner 186 are adjusted.

FIG. 33 shows the hardware configuration of the communication control unit 176 when the space diversity system has four channels. The communication control unit 176 includes a transmission system control unit 194, a main reception system control unit 195, an SD reception system control unit 196, an infinite phase shifter control unit 197, and a CPU 198 as an original communication control unit 176. Here, the transmission control unit, the main reception control unit, the SD reception control unit, and the infinite phase shifter control unit 191 are shared by the communication control unit 176 by using the CPU 198.

The transmission system control section 194 fetches a transmission output detection signal obtained from the transmission output detection circuit (equivalent to 148) of the transmission main signal section 181 of the outdoor radio sections 171 to 174 for each device, and performs monitoring processing of each outdoor radio section. Then, the data is output to the outside via the CPU 198 of the communication control unit 176.

In the main reception system control unit 195 and the SD reception system control unit 196, the reception input detection circuit (corresponding to 152) of the reception main signal unit 185 of the outdoor radio units 171 to 174 and the reception output detection circuit (corresponding to 152) of the SD reception main signal unit 188. A signal is taken in by each device, a monitoring process of each outdoor wireless unit is performed, and the signal is output to the outside via the CPU 198.

Further, the transmission system control unit 194 detects an abnormal transmission output (excessive output / low output) from the acquired transmission monitor value, generates an alarm signal, and outputs the signal to the outside via the CPU 198 of the communication control unit 176. . Similarly, the main reception system control unit 195 and the SD reception system control unit 196 detect an abnormality of the reception input (excessive input / low input) from the acquired main and SD reception monitor values, generate an alarm signal, and perform communication. Output to the outside via the CPU 198 of the control unit 176.

Further, the infinite phase shifter control unit 197 uses the phase difference signals from the in-phase combiners 186 of the outdoor wireless units 171 to 174 to perform an infinite phase shift for making the phases of the main and SD signals of each outdoor wireless unit in phase. An in-phase shifter is generated and supplied to the infinite phase shifter 189 of the outdoor wireless units 171 to 174 via the CPU 198 of the communication control unit 176 to perform infinite phase shifter control.

FIG. 34 shows a flowchart of processing of the transmission system control unit, the main reception system control unit, the SD reception system control unit, the communication control unit, and the infinite phase shifter control unit. The transmission system control section 194 performs transmission monitoring processing and alarm detection processing of each outdoor radio section in steps S1, S2, and S3 shown in FIG.

Next, in steps S4 and S5, the main reception control section 195 performs main reception monitoring processing for each outdoor radio section, and in the SD reception system control section 196, performs step S6 and step S7 for SD reception monitoring processing for each outdoor radio section. Do. In step S8, the communication control unit 176 performs main and SD reception alarm processing for each outdoor device, and in step S9, collectively communicates transmission / reception monitoring and transmission / reception alarms for each outdoor wireless unit.

The infinite phase shifter control section 197 performs the interrupt processing shown in FIG. 34- (b) at regular time intervals, and performs infinite phase shifter control at steps S11 and S12, thereby always performing control at regular time intervals. To do.

FIG. 35 shows a processing sequence in the case where the series of processing shown in FIG. 34 is time-divided by the outdoor radio unit of four channels. Each of the outdoor wireless units 171 to 174 executes a process other than the interruption at a fixed time interval T, and makes the processing time of each outdoor wireless unit uniform.

As described above, according to the present invention, the reference signal generator 177 mounted on the outdoor common units 135 and 175 establishes the reference signal synchronization of the PLL circuits 182 of all the outdoor wireless units 131 to 134 and 171 to 174. Is possible. Further, even in severe outdoor requirements, the reference signal generator 177 requires only one circuit, so that the cost increase can be reduced even if a highly reliable reference generator is applied.

Further, the transmission control and the reception control are shared by the communication control units 136 and 176, and time-division multiplexing control is performed, so that one communication control unit 136 and 176 can cope with the control and downsizing can be achieved. . Further, by separating the outdoor common units 135 and 175 and the outdoor wireless units 131 to 134 and 171 to 174, the number of channels can be increased by adding only the outdoor wireless unit, which is the largest heat generating unit of the outdoor wireless unit. Since the HPA (High Power Amp) is separate from the outdoor common use unit, the thermal design of the outdoor common use unit and the outdoor wireless communication unit can be individually and easily performed. Also, the number of cable connection interfaces can be reduced when a co-channel is configured.

Since there is no setting related to the radio frequency in the outdoor common units 135 and 175, when the channel is added, only the band-pass filters 143, 144, 183, 184 and 187 of the outdoor radio units 131 to 134 and 171-174 need to be replaced. Channels can be added to the outdoor common units 135 and 175 without mechanical influence. In addition, the outdoor wireless unit and the common use unit are physically separated,
A data holding unit is provided in the outdoor wireless unit, and the adjustment data obtained during the test is held in the data holding unit. When the outdoor wireless unit is connected to the outdoor common unit, the outdoor common unit is connected to the outdoor wireless unit. By reading the adjustment data from the data holding unit and controlling the common outdoor unit based on the adjustment data, it is not necessary to test the outdoor wireless unit at the time of extension, and the extension can be performed easily.

It should be noted that the present invention may be configured as described in the following supplementary notes.
(Appendix 1)
A radio transmitting / receiving unit for performing modulation / demodulation processing;
A common unit that controls the operation of the wireless transmission and reception unit,
The wireless device for outdoor installation, wherein the wireless transmitting / receiving unit is attached to the common unit so as to be exposed to outside air.
(Appendix 2)
The outdoor installation wireless device according to claim 1, wherein a plurality of the wireless transmission / reception units can be attached to the common unit.
(Appendix 3)
The common unit includes a transmission / reception unit interface unit including a connector,
The wireless transmission / reception unit includes a common unit interface unit including a connector on a side attached to the common unit,
The wireless transmission / reception unit is electrically connected to the common unit by fitting the connector of the interface unit for the common unit into the connector of the interface unit for the wireless transmission / reception unit. 3. The wireless device for outdoor installation according to 2.
(Appendix 4)
The wireless device for outdoor installation according to claim 3, wherein at least one of the connector of the interface unit for the wireless transmission / reception unit or the connector of the interface unit for the common unit is held in a floating manner within a mounting surface. .
(Appendix 5)
The outdoor installation according to claim 3 or 4, wherein a waterproof member is provided on a surface of the common unit interface of the wireless transmission / reception unit that contacts the interface for the wireless transmission / reception unit of the common unit. For wireless devices.
(Appendix 6)
The wireless transmitting and receiving unit includes a housing having a heat radiation member on a side mounted with the electronic device and mounted on the common unit,
The electronic device directly or indirectly contacts the housing or the heat dissipation member,
The wireless device for outdoor installation according to Supplementary notes 1 to 5, wherein heat generated from the electronic device is transmitted to the outside air via the housing or the heat radiating member.
(Appendix 7)
7. The outdoor installation wireless device according to claim 6, wherein the wireless transmission / reception unit forms a gap between the heat radiation member provided in the housing and the common unit and is attached to the common unit.
(Appendix 8)
The wireless transmission / reception unit includes a shaft member on the side attached to the common unit and above the common unit interface unit,
The common unit includes a bearing unit above the wireless transmitting and receiving unit interface unit,
8. The outdoor installation wireless device according to claim 3, wherein the wireless transmission / reception unit is connected to the common unit by hooking the shaft member on the bearing unit and rotating.
(Appendix 9)
The common part is
A power supply unit that converts a primary power supply into a secondary power supply and supplies power to electronic components mounted on the common unit;
A control unit that monitors the wireless transmitting / receiving unit attached to the common unit, controls a demultiplexing unit that selects a signal and distributes the signal to the wireless transmitting / receiving unit,
9. The outdoor installation wireless device according to claim 1, further comprising a switching unit that switches a wireless transmitting / receiving unit used in the plurality of wireless transmitting / receiving units attached to the common unit.
(Appendix 10)
The electronic device mounted on the housing of the wireless transmitting and receiving unit,
A power supply unit for supplying power to electronic components mounted on the wireless transmitting / receiving unit;
A microwave transmitter for converting information to be transmitted into a signal,
A microwave receiving unit that converts a received signal into information,
The wireless device for outdoor installation according to Supplementary Notes 6 to 9, further comprising a modulation / demodulation unit that modulates and demodulates the signal wave.
(Appendix 11)
Attached to a substantially box-shaped common unit having a function of transmitting and receiving wireless signals via an antenna, performs demodulation processing on an input wireless signal of the common unit, outputs a demodulated signal to the common unit, Performing a modulation process using an input wireless signal from a common unit, a wireless unit incorporating a modulation and demodulation unit that outputs a modulated wave to the common unit,
When attaching the modulation and demodulation unit to the common unit, the connector unit on the side of the common unit is fitted, and a connector unit for transmitting and receiving signals including the wireless signal,
An attaching portion for attaching to a side surface of the common portion,
A wireless unit comprising a heat radiation structure for suppressing a rise in temperature in the modulation / demodulation unit.
(Appendix 12)
In a plurality of wireless units performing modulation and demodulation of each of a plurality of wireless channels, and in the outdoor installation wireless device having a common unit to which the plurality of wireless units and antennas and indoor devices are connected,
A reference signal generation unit that generates a reference signal and supplies the reference signal to a PLL circuit of each of the plurality of wireless units;
A wireless device for outdoor installation, comprising: a communication control unit that performs transmission / reception monitoring of each of the plurality of radio units by time division multiplexing and controls transmission / reception main signals of each of the plurality of radio units by time division multiplexing.
(Appendix 13)
The antenna is a main antenna that transmits and receives wireless signals,
Having a space diversity side antenna for receiving radio signals,
The plurality of radio units, a transmission main signal unit that modulates a transmission signal,
A first reception main signal unit for demodulating a reception signal of the main antenna;
A second reception main signal unit that demodulates a reception signal of the space diversity side antenna;
13. The wireless device for outdoor installation according to claim 12, further comprising an in-phase combiner for combining and outputting the output signals of the first and second reception main signal units in the same phase.
(Appendix 14)
A phase shifter that shifts a phase of a local oscillation signal supplied from the PLL circuit to the first main signal unit and supplies the local oscillation signal to the second main signal unit;
A phase difference detection circuit that detects a phase difference between output signals of the first and second reception main signal units in the in-phase combiner,
The common unit receives the phase difference information from the phase difference detection circuits of the plurality of wireless units by time division multiplexing, and controls the phase shifters of the plurality of wireless units by time division multiplexing. 14. The wireless device for outdoor installation according to supplementary note 13, wherein the wireless device further comprises a unit.
(Appendix 15)
The plurality of radio units have a delay adjuster that delays one of the output signals of the first and second reception main signal units,
15. The outdoor-installation wireless device according to claim 13, wherein the common unit includes a variable delay control unit that performs variable control of the delay adjusters of the plurality of wireless units by time division multiplexing.
(Appendix 16)
16. The outdoor-installed wireless device according to claim 12, wherein the plurality of wireless units perform transmission and reception using different channel frequencies.
(Appendix 17)
16. The outdoor-installed wireless device according to claim 12, wherein the plurality of wireless units perform transmission / reception with different horizontal and vertical polarizations at the same channel frequency for every two channels.
(Appendix 18)
The plurality of wireless units have a holding unit that holds adjustment data,
18. The outdoor installation wireless device according to claim 12, wherein the common unit controls the connected wireless unit based on adjustment data read from the holding unit of the connected wireless unit.

It is an exploded perspective view of the conventional outdoor installation radio equipment 1. FIG. 1 is an exploded perspective view illustrating an appearance of a wireless device for outdoor installation 10 according to the present invention. FIG. 3 is a diagram illustrating an appearance of a common unit 20. FIG. 3 is a diagram illustrating an internal structure of a common unit 20. FIG. 3 is a diagram illustrating an appearance of a wireless transmission / reception unit 50-1. FIG. 2 is an exploded perspective view showing a schematic configuration of a wireless transmission / reception board 51. FIG. 9 is a perspective view showing a state in which a microwave transmitting unit 70, a power supply unit 71, and a microwave receiving unit 72 are mounted on a back member 54. FIG. 8 is a perspective view showing a state in which a heat pipe housing 65 is further mounted on the back member 54 in the state shown in FIG. 7. FIG. 9 is a perspective view showing a state in which a first modem 61 is further mounted in the state shown in FIG. 8. FIG. 10 is a diagram illustrating the rear member 54, the heat pipe housing 65, the first modulation / demodulation unit 61, and the like illustrated in FIG. 9 when viewed from the Y2-Y1 direction in FIG. FIG. 11 is a diagram showing a state where the second modem 62 is attached to the first modem 61 in the state shown in FIG. FIG. 3 is a diagram illustrating a heat radiation structure of a wireless transmission / reception board 51. FIG. 4 is a diagram illustrating details of a structure of a common unit interface unit 55 of the wireless transmission / reception unit 50-1. FIG. 2 is a schematic diagram showing a structure of a first connector section 100. FIG. 3 is a schematic diagram showing a relationship between a fixing plate 210, a fixing screw 200, and a screw receiving portion 101 of the first connector portion 100. FIG. 4 is a schematic diagram illustrating a side cross section of a second connector unit 320 of a transmission / reception unit interface unit 24 of the common unit 20 illustrated in FIG. FIG. 9 is a diagram schematically illustrating a state in which a third connector unit 340 is attached to a transmission / reception unit interface unit 24 using an attachment unit 360. FIG. 3 is a diagram illustrating a structure for attaching a wireless transmitting / receiving unit to a common unit. It is a block diagram of the reference example of the radio | wireless apparatus for outdoor installation of 1 channel structure. It is a block diagram of the reference example of the radio | wireless apparatus for outdoor installation of a 4-channel structure. FIG. 4 is a configuration diagram of a reference example of a local oscillator 98. FIG. 4 is a configuration diagram of a four-channel configuration local oscillator using a local oscillator 98. 5 is a configuration diagram of a local oscillator having a two-channel co-channel configuration using a local oscillator 98. FIG. It is a block diagram of the radio equipment for outdoor installation of a 4 channel composition concerning the present invention. FIG. 3 is a configuration diagram of a local oscillator in a four-channel configuration according to the present invention. FIG. 5 is a diagram for describing time division multiplexing control in a four-channel configuration according to the present invention. It is explanatory drawing of four-channel time division multiplex control. It is the schematic of the outdoor radio | wireless apparatus of a space diversity combining reception system. FIG. 1 is a block diagram of a wireless device for outdoor installation in a space diversity type 4 channel configuration according to the present invention. FIG. 4 is a diagram for describing control of an infinite phase shifter. FIG. 4 is a diagram for describing control of an infinite phase shifter. FIG. 4 is a diagram for describing control of a delay adjuster. FIG. 7 is a hardware configuration diagram of a communication control unit 176 when a space diversity scheme has four channels. It is a flowchart of a process of a transmission system control unit, a main reception system control unit, an SD reception system control unit, a communication control unit, and an infinite phase shifter control unit. This is a processing sequence when time division is performed by an outdoor wireless unit of four channels.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 10 Outdoor housing 20 Common part 24 Interface part for transmission / reception part 25 Bearing part for transmission / reception part 30 Power supply part of common part 31 Switching part 32 Control part 33 Demultiplexing part 50-1 to 50-4 Wireless transmission / reception part 55 Interface part for common part 55-1 Surface of Common Unit Interface Unit 56 Common Unit Hook Shaft Member 57 Heat Dissipation Fin 58 Waterproof Packing 60 Waterproof Housing 61 First Modulation / Demodulation Unit 62 Second Modulation / Demodulation Unit 70 Microwave Transmitter 71 Power Supply Unit for Wireless Transmitter / Receiver 72 Microwave receivers 131 to 134, 171 to 174 Outdoor wireless unit 135, 175 Outdoor common unit 136, 176 Communication control unit 137, 177 Reference signal generator 138, 178 Indoor unit 141, 185 Transmission main signal unit 142, 182 PLL circuit 143,144 Bandpass filter 145,185,188 Reception Signal section 179 Main side antenna 180 SD side antenna 186 In-phase combiner 189 Infinite phase shifter 190 Delay adjuster 191 Infinite phase shifter control section 192 Phase difference detection circuit 194 Transmission system control section 195 Main reception system control section 196 SD reception system Control unit 197 Infinite phase shifter control unit 198 CPU

Claims (5)

A radio transmitting / receiving unit for performing modulation / demodulation processing;
A common unit that controls the operation of the wireless transmission and reception unit,
The wireless device for outdoor installation, wherein the wireless transmitting / receiving unit is attached to the common unit so as to be exposed to outside air. The common unit includes a transmission / reception unit interface unit including a connector,
The wireless transmission / reception unit includes a common unit interface unit including a connector on a side attached to the common unit,
2. The wireless transmission / reception unit is electrically connected to the common unit by fitting the connector of the common unit interface unit into the connector of the wireless transmission / reception unit interface unit. The wireless device for outdoor installation according to the above. The outdoor unit according to claim 2, wherein a waterproof member is provided on a surface of the common unit interface of the wireless transmission / reception unit that contacts the interface unit for the wireless transmission / reception unit of the common unit. Wireless device. The wireless transmitting and receiving unit includes a housing having a heat radiation member on a side mounted with the electronic device and mounted on the common unit,
The electronic device directly or indirectly contacts the housing or the heat dissipation member,
The wireless device for outdoor installation according to any one of claims 1 to 3, wherein heat generated from the electronic device is transmitted to outside air via the housing or the heat radiating member. A plurality of wireless units that perform modulation and demodulation of each of a plurality of wireless channels, and a wireless device for outdoor installation having a common unit to which the plurality of wireless units and the antenna are connected,
A reference signal generation unit that generates a reference signal and supplies the reference signal to a PLL circuit of each of the plurality of wireless units;
A wireless device for outdoor installation, comprising: a communication control unit that performs transmission / reception monitoring of each of the plurality of radio units by time division multiplexing and controls transmission / reception main signals of each of the plurality of radio units by time division multiplexing.

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