JPH09233011A - Cordless telephone set - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the utilizing efficiency of a master set and to extend a range of location of a slave set to outdoor by providing a means selecting communication and an outdoor repeater. SOLUTION: An outer conductor 77 and its skirt 78 of an outdoor repeater 36 have a water-proof structure. A call signal from a slave set A37 is received by an antenna 6 of the outdoor repeater 36, amplified and detected by a receiver A7. An ID number and a destination number in a call signal are decoded by a control circuit A11 and sent to a control circuit B17 via a line changeover circuit 38. A dialing from the line changeover circuit 38 to a telephone line 39 is allowed by the control circuit B17 when the ID number received from the slave set A37 indicates a specific registration number for external dialing and the dialing to an external device is made. In the case of a usual registration number, the line changeover circuit 38 and a handset 40 are connected to make a call to a master set 35.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cordless telephone device for performing wireless communication between a master unit and a slave unit.

[0002]

2. Description of the Related Art First, a conventional wireless relay device which is one of wireless related devices will be described. FIG. 10 shows, for example, "Mobile Communication-Theory and Design" published by The Institute of Electronics and Communication Engineers, page 96-
By analogy with Figure 5.1, Figure 5.2 and Figure 5.3 on page 99,
FIG. 11 is a block diagram of a wireless device used in a conventional automobile telephone device or the like, and FIG. 11 is a simplified diagram showing a frequency band of a wireless carrier wave used in the wireless device.

In the figure, (1) is a mobile communication device A (2)
A wireless relay device A that communicates with the mobile communication device B (3).
A wireless relay device B and (5) communicating with (4) are cables connecting the wireless relay device A (1) and the wireless relay device B (3). (6) is an antenna A for transmitting / receiving a wireless carrier wave to / from the mobile communication device A (2), and (7) is an antenna A
Receiver A for receiving a wireless carrier wave via (6), (8)
Is a transmitter A that transmits a wireless carrier wave through an antenna A (6), and (9) is a wireless carrier wave that is transmitted from the antenna A (6) to the receiver A (7) and from the transmitter A (8) to the antenna A.
The antenna duplexer A and (10) for demultiplexing to (6) are the synthesizer A, and the receiver A (7) is provided by this oscillation frequency.
And the operating frequency of transmitter A (8) is determined.

(11) is a control circuit A, which is a receiver A
(7), the transmitter A (8), and the synthesizer A (10) are controlled. Further, similarly to the above, (12) is antenna B, (13) is receiver B, (14) is transmitter B, (15) is antenna duplexer B, (16) is synthesizer B, and (17) is The control circuit B. Further, the wireless carrier wave received by the receiver A (7) is transmitted to the transmitter B (14) on the cable (5a), and similarly, the wireless carrier wave is transmitted from the receiver B (13) to the transmitter A (on the cable (5b). 8), the control circuit A (11) and the control circuit B (17) are connected by the cable (5c), and various kinds of information are exchanged with each other.

Further, regarding the frequency of the wireless carrier wave used in the above wireless device, the frequency transmitted from the mobile communication device A (2) and received by the wireless relay device A (1) is f.
_{Let RX1} be the frequency transmitted from the radio relay device A (1) to the mobile communication device A (2), f _TX1 , mobile communication device B.
Let f _RX2 be the frequency transmitted from (4) and received by the wireless relay device B (3), and f _TX2 be the frequency transmitted from the wireless relay device B (3) to the mobile communication device B (4). _TX1
And f _TX2 ) and (f _RX1 and f _RX2 ) are provided in close frequency bands, respectively, and in order to avoid mutual interference between the transmitting radio carrier and the receiving radio carrier (f _TX1 , f _RX2 ).
The frequency bands of _TX2 ) and (f _RX1 , f _RX2 ) are sufficiently separated.

Next, the operation will be described. Mobile communication device A
The wireless carrier transmitted from (2) is the wireless relay device A.
(1), mobile communication device B through wireless relay device B (3)
The process of transmission to (4) will be described. First, the radio carrier of the frequency f _RX1 transmitted from the mobile communication device A (2) is received by the antenna A (6), and the antenna duplexer A
The signal is demultiplexed at (9) and sent to the receiver A (7). The wireless carrier wave is detected by the receiver A (7) and sent as a reception baseband signal to the transmitter B (14) via the cable (5a). Then, the received baseband signal is transmitted by the transmitter B.
It is modulated by (14) and becomes a radio carrier of frequency f _TX2 , which is demultiplexed by antenna duplexer B (15) and antenna B
(12) is transmitted to the mobile communication device B (4).

On the contrary, the wireless carrier waves transmitted from the mobile communication device B (4) are the wireless relay device B (3) and the wireless relay device A.
The process of transmission to the mobile communication device A (2) via (1) will be described. Mobile communication device B (4) similar to the above process
From the radio carrier of frequency f _RX2 to antenna B (12)
Received by the antenna duplexer B (15) and the receiver B
(13), the cable (5b), the transmitter A (8) and the antenna duplexer A (9) are transmitted from the antenna A (6) to the mobile communication device A (2) as a radio carrier of frequency f _TX1. .

Next, a conventional cordless telephone device which is another wireless-related device will be described. FIG. 12 shows, for example, “Facility” 36, No. 3, 197, published by the Telecommunications Association of Japan.
It is a block diagram of the conventional cordless telephone device shown by the paper "new cordless telephone" of pages 9,134-141. In the figure, (6) to (10) are the same as or equivalent to those in the above-mentioned conventional example, and therefore the description thereof is omitted. (35)
Is the master unit, and (37) is the master unit (3 via the antenna A (6).
5) is a control / interface circuit, which is a receiver A (7), a transmitter A (8),
While controlling each operation of the synthesizer A (9),
A telephone line (39) is connected to exchange signals with the outside.

Next, the operation will be described. First, when there is an incoming call from the outside to the master unit (35) via the telephone line (39), the control / interface circuit (70) causes the transmitter A (8) to send out a calling signal, and the antenna duplexer A ( The calling signal is radiated into the space from the antenna A (6) via 9). Then, a call is established with the child device A (37) that has received the call signal. Here, the calling signal from the master unit (35) includes a specific registered ID number, and the slave unit A (37) corresponding to this ID number is called. Next, cordless handset A (3
When a call is made from 7) to the outside, the calling signal sent from the handset A (37) is received by the antenna A (6),
Demultiplexed by the antenna duplexer A (9), received and detected by the receiver A (7), control and interface circuit (70)
From the telephone to the telephone line (39) as a calling signal. Here again, the master unit (35) accepts only the outgoing call from the slave unit A (37) including the ID number of the specific registration in the call signal.

In addition, incoming calls and outgoing calls are not accepted except between the master unit (35) having a specific registered ID number and the slave unit A (37), and the master unit (35) itself is indoors. It was usually designed to be installed.
Next, a base station device that transmits and receives a wireless carrier wave that is another wireless related device will be described. FIG. 13 is, for example, “Antenna Engineering Handbook” edited by The Institute of Electronics and Communication Engineers, published by Ohmsha,
FIG. 8 is a diagram of a base station device including the conventional monopole antenna with a skirt shown in FIGS. 5 and 7 on page 137. In the figure, (71) is a radiating element of the antenna, (19) is a coaxial outer conductor, (72) is a skirt C made of the outer conductor (19), and (22) is water flowing into the outer conductor (19). (73) is a coaxial inner conductor, (7)
4) is a coaxial connector for connecting the coaxial cable (75),
(76) is a base station apparatus main body, and (50) is a signal cable connection terminal.

Next, the operation will be described. The lengths of the radiating element (71) and the skirt C (72) of the antenna are set to about 1/4 of the wavelength of the used frequency. As a result, the skirt C (72) constitutes a coaxial line with the outer conductor (19), and is brought into resonance with the operating frequency of the wireless carrier wave transmitted / received from the radiating element (71) to the coaxial cable (74). Even if 75) is connected, the base station device body (76) is not affected by the radio carrier wave.
The signal can be transmitted and received via the coaxial cable (75).
As a result, the radiating element (71) and the skirt C (72) form a half-wave dipole antenna, and exhibit good radiation characteristics. Then, a signal is transmitted / received to / from the outside through the connection terminal (10).

[0012]

Since the conventional cordless telephone system is constructed as described above, the master unit (3) is used except for the slave unit A (37) having a specific registered ID number.
5) Cannot communicate with the parent machine (35) and cannot use the parent machine (35) jointly, and the parent machine (35) is only a relay role between the child machine A (37) and the outside. Since there is no method, there is a problem of low utilization efficiency.
Since the installation location of 5) is usually indoors, cordless handset A (37)
There was a problem that the range of the use place of was limited to indoors.

The present invention has been made to solve the above-mentioned problems, and improves the utilization efficiency of the master unit, and
It is an object of the present invention to obtain a cordless telephone device capable of expanding the range of usage locations of a child machine outdoors.

[0014]

In a cordless telephone device according to the present invention, at least a slave unit used outdoors, a master unit connected to a telephone line and installed indoors, and a master unit connected to this master unit. An outdoor relay device provided outdoors for communicating with the slave device, and based on an identification signal in a wireless carrier received from the slave device by the outdoor relay device, communication between the slave device and the master device, Alternatively, a cordless telephone device including a selection unit that selects one of communication between the slave unit and the outside through the telephone line, and a waterproof unit that has a waterproof structure in an outer shell of the outdoor relay device.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1. FIG. 1 is a block diagram showing the first embodiment, FIG. 2 is a simplified diagram showing a frequency band of a wireless carrier wave used in this wireless device, and FIG. 3 is a simplified configuration diagram of an adjuster. ) Is a wireless relay device that relays wireless communication between the mobile communication device A (2) and the mobile communication device B (4),
(6) is an antenna A that communicates with the mobile communication device A (2),
(12) is an antenna B that communicates with the mobile communication device B (4), (19) is an outer conductor A of a coaxial line forming the outer shell of the wireless relay device (18), and (20) and (21) are A skirt A and a skirt B respectively showing the skirt portion of the outer conductor A (19), and the skirt A (20) is the antenna A.
(6) has a length of one-quarter wavelength of the wireless carrier wave transmitted from (6), and the skirt B (21) has a length of one-quarter wavelength of the wireless carrier wave from the antenna B (12). (22)
Is a waterproof ring provided in the vicinity of the antenna A (6) and the antenna B (12) and the outer conductor A (19), and prevents water from flowing into the outer conductor A (19).

(9) is an antenna duplexer A, (7) is a receiver A, (8) is a transmitter A, (10) is a synthesizer A,
(15) is an antenna duplexer B, (13) is a receiver B,
(14) is transmitter B, (16) is synthesizer B, (2
3) is a demultiplexer A that demultiplexes the wireless carrier wave sent from the transmitter A (8) to the antenna duplexer A (9), and (24) is a regulator that changes the amplitude and phase of the demultiplexed wireless carrier wave. A and (25) are from antenna duplexer B (15) to receiver B
A synthesizer B for synthesizing the wireless carrier from the regulator A (24) with the wireless carrier sent to (13), similarly (26)
Is a demultiplexer B, (27) is a regulator B, and (28) is a combiner A.
It is.

(29) is receiver A (7), transmitter A
(8), synthesizer A (10), adjuster A (24),
Receiver B (13), transmitter B (14), synthesizer B
(16) is a control circuit for controlling the operation of the adjuster B (27), and is wireless from the receiver A (7) to the transmitter B (14) and from the receiver B (13) to the transmitter A (8). It also has the function of a carrier wave transmission line. (30) is the outer conductor A (19)
It is an inlet provided on the side of the power supply to supply power to the wireless repeater (18).
Furthermore, a waterproof ring (22) is fitted to prevent the inflow of water.

The description of f _TX1 , f _TX2 , f _RX1 and f _RX2 indicating the frequencies used for the radio carrier is omitted because it is the same as the conventional example, but the antenna A (6) is used for the frequency band. As shown in FIG. 2, f _TX1 and f _RX1 have a sufficient interval in order to easily branch the wireless carrier wave transmitted and received by the antenna duplexer A (9), and the same applies to f _TX2 and f _RX2 . Furthermore, f _TX1 and f _RX2 , f
_RX1 and _fTX2 are provided in the close frequency band.

Further, (31) is a variable attenuator A for varying the amplitude of the wireless carrier wave from the duplexer A (23), and (32).
Is a variable phase shifter A for varying the phase of this wireless carrier wave. Similarly, (33) and (34) are the demultiplexers B (2
6) A variable attenuator B and a variable phase shifter B for varying the amplitude and phase of the wireless carrier wave from 6). In addition, each variable attenuator and variable phase shifter are controlled by a control circuit (29).

Next, the operation will be described. First, the skirt A (20) causes the outer conductor A (19) to resonate with the radio carrier transmitted from the antenna A (6), so that the outer conductor A (19) and the antenna A (6) are insulated, Similarly, the skirt B (21) allows the outer conductor A (1
9) and the antenna B (12) are insulated. This prevents the radio carrier wave from becoming a high-frequency current and flowing between the antennas via the outer conductor A (19).
The antennas are prevented from being coupled to each other via 9).

Next, communication between the mobile communication device A (2) and the mobile communication device B (4) via the wireless repeater (18) will be described. Frequency f _RX1 transmitted from mobile communication device A (2)
Is received by the antenna A (6), passes through the antenna duplexer A (9) and the combiner A (28), and is detected by the receiver A (7). After that, the control circuit (29)
After being transmitted to the transmitter B (14) via the antenna, modulated and amplified, the radio wave of the frequency f _TX2 is transmitted from the antenna B (12) through the duplexer B (26) and the antenna duplexer B (15). It is radiated as a carrier wave to the mobile communication device B (4).

Further, the radio carrier of the frequency f _RX2 transmitted from the mobile communication device B (4) passes through the antenna duplexer B (15) and the combiner B (25) as in the above, and then is received by the receiver B.
After being detected by (13), it passes through the control circuit (29), is modulated and amplified by the transmitter A (8), and passes through the demultiplexer A (23) and the antenna duplexer A (9) to the antenna A ( It is radiated from 6) to the mobile communication device A (2) as a radio carrier of frequency f _TX1 .

Here, with respect to the wireless carrier waves received by the antenna, there are those transmitted from another antenna in addition to those transmitted from a predetermined mobile communication device. This is the coupling of the antennas through the space, but the intrusion of the wireless carrier from this other antenna lowers the reception sensitivity of the wireless carrier from the mobile communication device that should be originally received, so its prevention will be described. Frequency f indicating the first radio carrier received by antenna B (12) indicating the first antenna
The wireless carrier of the frequency f _{TX 1} (hereinafter, referred to as “the wireless carrier f _RX2 ”) indicating the second wireless carrier transmitted from the antenna A (6) indicating the second antenna on the wireless carrier of the _{RX 2} (hereinafter referred to as “wireless carrier f _RX2 ”). A description will be given of a decrease in reception sensitivity when a wireless carrier wave f _TX1 ”is entered.

For example, antenna A (6) and antenna B
The coupling loss in the space between (12) is 30 [dB], and the output of the wireless carrier wave f _TX1 from the transmitter A (8) is 10 [m].
W] = 123 [dBμV], the antenna B (1
In 2), the wireless carrier f _TX1 is 93 [dBμV] (= 12
3-30) and the loss of the antenna duplexer B (15) and the combiner B (25) is 3 [dB], 90 [dB]
μV] (= 93-3) enters the receiver B (13).
Therefore, the sensitivity suppression characteristic of the receiver B (13) is set to 80 [d
B], and if the intruding wireless carrier wave f _TX1 is further suppressed by -10 [dB] below this, 20 [dB] (= 9
It requires a reduction in invasion of only 0-80 + 10).

Therefore, antenna A (6) and antenna B
It is effective to widen the interval of (12), but there is a limit to this. Therefore, the wireless carrier wave f _TX1 sent from the transmitter A (8) to the antenna duplexer A (9) is connected to the demultiplexer A.
The variable attenuator A in the regulator A (24) is demultiplexed at (23).
The amplitude and the phase are adjusted by using (31) and the variable phase shifter A (32) to obtain the wireless carrier wave f _TX11 . And antenna B
When the wireless carrier wave f _TX1 received by (12) is sent from the antenna duplexer B (15) to the combiner B (25), the wireless carrier wave f _TX11 by the adjuster A (24) is combined to _{generate the} wireless carrier wave f _TX1. Erase _TX1 .

That is, the transfer function E _X1 of the radio carrier f _TX1 radiated from the antenna A (6) and entering the antenna B (12) is expressed as E _X1 = Axsin (WT _X1 + φX) [where A _X : amplitude, φ _X : phase, W: angular frequency] and the transfer function E _X11 of the wireless carrier wave f _TX11 from the demultiplexer A (23) via the adjuster A (24) is expressed as E _X11 = Aisin (WT _X1 + φ _i ) [however, , A _i : amplitude, φ _i : phase, W: angular frequency].

Therefore, the transfer function Ex of the wireless carrier wave synthesized by the synthesizer B (25) is given by E _X = Ax sin (W
T _X1 + φ _X ) + Aisin (WT _X1 + φ _i ), and A _i
= A _X , φ _i = φ _X −π Adjuster A (24)
When the amplitude and the phase of the wireless carrier f _{TX 11} are adjusted, E _X = 0, and the wireless carrier f entering from the antenna B (12)
_TX1 can be erased. This makes it possible to suppress the intrusion of 20 [dB] of the wireless carrier wave f _TX1 described above.

Similarly, from antenna B (12) to antenna A
For elimination of intrusion of the wireless carrier wave f _TX2 into (6),
Splitter B (26), adjuster B (27), combiner A (2
According to 8), the wireless carrier wave f _TX21 is coupled to the wireless carrier wave f _TX1 and the wireless carrier wave f _TX2 is erased.

In the above embodiment, the antenna provided with the skirted monopole antenna is shown, but various antennas such as a plate antenna, a folded antenna and a collinear antenna may be provided. Further, in the above-mentioned embodiment, the one-opposed wireless repeater (18) is described, but a plurality of opposed wireless repeaters may be used. Further, in the above embodiment, the variable attenuator and the variable phase shifter are always freely adjusted by the control circuit (29). However, once the adjustment is performed, the variable attenuator and the variable phase shifter may be fixed thereafter, or may be periodically adjusted. Good.
Further, in the above embodiment, one adjuster is provided for each radio carrier to be transmitted, but a plurality of adjusters may be provided when the air coupling between the antennas is caused by multiple propagation.

Embodiment 2 FIG. Next, an embodiment of the present invention will be described. FIG. 4 is a block diagram of a cordless telephone device having one child device showing an embodiment of the present invention, and FIG. 5 is a cordless telephone device having two child devices showing another embodiment of the present invention. It is a block diagram.

In the figure, (36) is an outdoor relay device connected to the master unit (35), and (77) is an outer conductor B showing an outer shell of the outdoor relay device (36), which has a waterproof structure. With the waterproof ring (22), water is prevented from entering the outdoor relay device (36) due to rain, snow, or the like. (7
8) is a skirt D showing the skirt portion of the outer conductor B (77), which has the same waterproof structure as the outer conductor B (77) and also has a quarter of the wireless carrier wave transmitted from the antenna A (6). It has a length corresponding to the wavelength. These outer conductors B
(77), the waterproof ring (22), and the skirt D (78) represent waterproofing means.

(6) to (17), (20), (35),
Since (37) and (39) are the same as or equivalent to those in the above-described conventional example or the above-described embodiment, description thereof will be omitted.
A line switching circuit (38) connects the telephone line (39), the control circuit A (11), the control circuit B (17), and the handset (40) for transmitting and receiving. (4
1) is a numeric keypad for dialing a telephone number, (42) is a display section for displaying various kinds of incoming / outgoing calls, and (43)
Is a memory for storing various information, and the numeric keypad (4
1), the display section (42), and the memory (43) are controlled by a control circuit B (17) showing a selecting means. (4
Reference numeral 4) is a slave unit B that communicates via the antenna B (12).

Further, the master unit (35) is installed indoors of a general household, the outdoor relay device (36) is provided at a predetermined outdoor height, and the master unit (35) and the outdoor relay device (36) are provided. Are connected by a coaxial line. In addition, the cordless handset A (37) is mainly used outdoors and has a service area within which communication with the outdoor relay device (36) is possible within about 500 m. Handset B (4
4) is mainly used near the indoor base unit (35) and communicates indoors.

Next, the operation will be described with reference to FIG. First, when a call is made from the handset A (37), the handset A
The wireless carrier, which is the calling signal from (37), is the antenna A.
After being received by (6) and being demultiplexed by the antenna duplexer A (9), amplification and detection are performed by the receiver A (7). After that, it is sent to the control circuit A (11) and the ID in the calling signal is sent.
The number and the destination number are decoded and the line switching circuit (3
It is transmitted to the control circuit B (17) via 8). In the control circuit B (17), the ID number transmitted from the slave unit A (37) is collated in the ID number memory area in the memory (43), and when the specific registration number for external call is made, the line switching circuit (38) From the telephone to the telephone line (39) is permitted and the call is made to the outside. At the time of the normal registration number, the line switching circuit (38) and the handset (40) are connected to the master unit (35). Is called, and communication between the child device A (37) and the parent device (35) is performed.

Next, the operation will be described with reference to FIG. Calling from the handset A (37) to the telephone line (39) and communication between the handset A (37) and the base unit (35) are omitted because they are the same as those described in FIG. Various communications using (44) will be described. When a call is made from the handset B (44), a wireless carrier wave, which is a call signal from the handset B (44), is received by the antenna B (12), and the antenna duplexer B (15) and the receiver B (13) are received. ) Via control circuit B (1
7). The control circuit B (17) decodes the ID number and the other party's number in the calling signal, and the memory (43)
In the ID number memory area inside, when the registration number for external call is made, the line switching circuit (38) and the telephone line (39) are connected to make an outgoing call, and also to the master unit (35). At the registration number of the communication of the line, the line switching circuit (38) and the handset (40) are connected, and the master unit (3)
5), and when the communication number with the handset A (37) is registered, the line switching circuit (38) and the control circuit A are used.
(11) is connected and communicates with the slave unit A (37) through the outdoor relay device (36).

In the above-mentioned embodiment, one main unit (35) and one outdoor relay device (36) are provided, but a plurality of each or either one may be provided. In the above embodiment, the outdoor relay device (36) is provided with the outer conductor D (78) of the coaxial line on the skirt A (20), but a ground wire or a ground plate having a waterproof structure is provided. Good. Further, although the coaxial line is provided for connecting to the parent device (35) of the outdoor relay device (36), a metal pipe may be used, and in this case, the metal pipe plays a role of a support. Further, if an ID number capable of communicating with the slave unit A (37) is registered in a master unit other than the master unit (35), the slave unit A (37) can communicate with the master unit. Further, if the base unit (35) has a transfer function, it is possible to connect a cordless telephone device having an ID number that is normally registered to the telephone line.

Embodiment 3 FIG. 6 shows a base station apparatus according to the third embodiment, which uses a towed tube dipole antenna. FIG. 7 is a block diagram of a base station device using a discone antenna showing another embodiment of the third embodiment. In the figure, (2), (6) to (1
Since 1), (19), (20), and (22) are the same as or equivalent to those in the above-described conventional example or the above-described embodiment, description thereof will be omitted.

Reference numeral (45) denotes a base station device, which is a control circuit A
(11) controls the receiver A (7), the transmitter A (8), and the synthesizer A (10), and also interfaces the transmitter A (7) and the receiver A (8) with the outside.
(46) and (47) are winding A and winding B of the hybrid transformer, (48) is a coupling capacitor, (49) is a DC voltage supply terminal, (50) is a signal cable connection terminal,
(51) is the conical base plate of the DISCON antenna, (52)
Indicates a dedicated control line for interfacing with the control circuit A (11).

Here, the antenna A (6) and the conical bottom plate (51) represent an antenna, the outer conductor A (19) having the skirt A (20) represents the outer shell of the coaxial cable,
Antenna duplexer A provided in the outer conductor A (19)
The whole of (9) -control circuit A (11) and winding A (46) -supply terminal (49) is a wireless part, and a connection terminal (50).
Indicates a connection part.

Next, the operation will be described with reference to FIG. First, the length of the skirt A (20) is the base station device (4
The skirt A (20) and the outer conductor A (19) are in a resonance state because the wavelength is set to a quarter of the wavelength of the operating frequency of 5), and the outer conductor A (19) is separated from the antenna A (6). It is insulated. In addition, the temperature rise of the entire base station device (45) due to direct sunlight is prevented, and deterioration and damage of internal parts are prevented. Also, a telephone line is connected to the connection terminal (50), and a DC voltage is applied from the telephone line by being superimposed on the voice signal. The DC voltage is separated by the coupling capacitor (47) and reaches the supply terminal (49). A DC voltage is supplied from the supply terminal (49) to each part of the base station device (45).

When calling the mobile communication device A (2) through the base station device (45), a tone signal is sent from the telephone line by superimposing it on the DC voltage and applied to the connection terminal (50). Then, the tone signal flows through the winding B (47) by the coupling capacitor (48), so that the winding A (4
A tone signal appears in 6). The control circuit A (11) decodes this tone signal, sends a call signal from the transmitter A (8) to call the corresponding mobile communication device A (2), and demultiplexes it at the antenna duplexer A (9). Then antenna A
Radiate from (6) into space.

Next, when a call is made from the mobile communication device A (2) via the base station device (45), the call signal is received by the antenna A (6) and split by the antenna duplexer A (9). After being waved, it is sent to the receiver A (7) for detection and is decoded by the control circuit A (11). And the control circuit A (11)
To send a tone signal to winding A (46)
A tone signal appears at (47) and is sent from the connection terminal (50) to the telephone line.

In FIG. 7, a cone base plate (51) of a discone antenna is provided in place of the skirt A (20), and the inside of the outer conductor A (19) is a disc-shaped radiating element of the discone antenna. Will be insulated. Furthermore, in addition to the connection terminal (50) connected to the telephone line, a dedicated control line (52) for interfacing with the control circuit A (11) is provided.
Various controls of 5) can be performed at high speed.

In the above embodiment, the skirt A (2
0) or conical base plate of the discone antenna (5
Although 1) is provided, a flat ground plane or ground wire may be used. Further, the antenna A (6) can be any type of antenna such as a linear folded antenna, a plate antenna, or an L-shaped / T-shaped blade antenna, and similar effects can be obtained.

Embodiment 4 FIG. 8 is a block diagram of a wireless device according to the fourth embodiment, and FIG. 9 is a diagram showing passage of communication time between the mobile communication device and the wireless relay device, in which (53) indicates the first movement. Mobile communication device C showing communication device
(54) and a mobile communication device D (5
A wireless relay device for relaying wireless communication of 5), (56)
Is an antenna C, (57) is connected to the antenna C (56), and is a high-frequency filter for removing noise of a transmitted / received wireless carrier wave, (58) is a receiver C, (59) is a transmitter C,
(60) is a synthesizer C, (61) is a high frequency filter (57), a receiver C (58) and a transmitter C (59).
Antenna switch for connecting either one of (62)
Is a control circuit C which is a control unit, (63) is a multiplexing / demultiplexing circuit, (64) is a relay switch A, (65) is a relay switch B, and (66) is a reception baseband signal output terminal A (hereinafter, reception output). Terminal A is abbreviated.), (67) is a reception baseband signal output terminal B (hereinafter abbreviated as reception output terminal B), and (68) is a transmission baseband signal output terminal B.
(Hereinafter, abbreviated as transmission output terminal B) and (69) are transmission baseband signal input terminals B (hereinafter, transmission input terminal B
Abbreviated. ).

In particular, in FIG. 9, t _RX1 and t _TX1 are time widths for transmission and reception of the mobile communication device C (54), and t _RX2 and t _TX2 are mobile communication device D (5), respectively.
It is the time width for transmitting and receiving 5).

First, communication between the mobile communication device and an external device (not shown) via the wireless repeater (53) will be described.
The wireless carrier wave transmitted from the mobile communication device C (54) is received from the antenna C (56) in the time width t _RX1 , and the noise is removed by the high frequency filter (57). And
It is sent to the receiver C (58) via the antenna switch (61) set on the receiver C (58) side, and after detection, it is converted into a reception baseband signal by the multiplexing / demultiplexing circuit (63). It is converted and transmitted from the reception output terminal A (66) to an external device. Further, the wireless carrier wave transmitted from the mobile communication device D (55) has an antenna C (56) with a time width t _RX2.
When it is received, it is transmitted from the reception output terminal B (67) to an external device through the high frequency filter (57), the antenna switch (61), the receiver C (58), and the multiplexing / demultiplexing circuit (63).

On the contrary, the transmission input terminal A (6
The transmission baseband signal input to 8) is encoded by the multiplexer / demultiplexer circuit (63), modulated by the transmitter C (59), and switched to the transmitter C (59) side antenna switch (61). _Is radiated from the antenna C (56) to the mobile communication device C (54) via the high frequency filter (57) with a time width t _TX1 . The transmission baseband signal input from the external device to the transmission input terminal B (69) is passed through the multiplexing / demultiplexing circuit (63), the transmitter C (59), the antenna switch (61), and the high frequency filter (57). Then, it is radiated from the antenna C (56) toward the mobile communication device D (55) with a time width t _TX2 .

Next, communication between mobile communication devices via the wireless relay device (53) will be described. First, the relay switch A (64) and the relay switch B (65) are turned on, and the reception output terminal B (67) and the transmission input terminal A (68), the reception output terminal A (66) and the transmission input terminal B (69). Connect each. Therefore, the wireless carrier wave transmitted from the mobile communication device C (54) to the wireless relay device (53) is received by the antenna C (56) in the time width t _RX1 . Then, the high frequency filter (57), the antenna switch (61), and the receiver C (5
8), relay switch B via the multiplexer / demultiplexer circuit (63)
Sent to (65) and makes a U-turn at this relay switch B (65), and again the multiplexer / demultiplexer circuit (63) and transmitter C (5
9), antenna switch (61), high frequency filter (5
7), mobile communication device D (55) via antenna C (56)
To the time width t _TX2 .

The transmission from the mobile communication device D (55) to the mobile communication device C (54) is performed in the same manner as described above, and the radio carrier wave transmitted from the mobile communication device D (55) is the time width t _RX2.
At the antenna C (56), the high frequency filter (5
7), antenna switch (61), receiver C (58),
Time from the antenna C (56) via the multiplexer / demultiplexer circuit (63), the relay switch A (64), the multiplexer / demultiplexer circuit (63), the transmitter C (59), the antenna switch (61), and the high frequency filter (57). Mobile communication device C (54) with width t _TX1
Is emitted to. As shown in FIG. 9, the relationship between the communication times of the mobile communication devices via the wireless repeater (53) is that the wireless carrier wave received in the time width t _RX1 is transmitted in the time width t _TX2 and the time width t _{TX2. The} radio carrier received by _RX2 has time width t
Sent on _TX1 . This prevents a plurality of wireless carriers from being transmitted / received at the same time and prevents mutual interference between wireless carriers.

Here, the control circuit C (62) controls the receiver C (58), the transmitter C (59), and the synthesizer C (6).
0), antenna switch (61), multiplexing / demultiplexing circuit (6)
3), relay switch A (64), relay switch B (6
5) etc. are controlled. In the above embodiment, the multiplexing / demultiplexing circuit (6
Relay switch A using the baseband signal from 3)
(64) and relay switch B (65) are shown to make a U-turn, but receiver C (58) and transmitter C (59)
May be connected to make a U-turn. Further, in the above embodiment, the one-stage relay using one wireless relay device (53) has been described, but multi-stage relay using a plurality of wireless relay devices (53) may be performed. Furthermore, in the above-described embodiment, a case has been described in which two pairs of transmission / reception time widths are provided on the time axis, but a plurality of mobile communication devices may be provided and one pair of time widths may be provided.

[0052]

Since the present invention is configured as described above, it has the following effects. Based on the identification signal from the slave unit received by the master unit by the selection means, it is determined whether or not communication with the slave unit is possible, communication between the slave unit and the outside or communication between the slave unit and the master unit is selected, and waterproof means Since the outdoor repeater having the above is installed outdoors, the range of the use place of the handset can be dramatically expanded, and it can be used more conveniently, and the base unit is the base station of the cordless telephone device, and the same identification signal can be used. There is an effect that it can be used jointly with a plurality of child devices that can send and receive, and the efficiency of use of the parent device can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram of a wireless device showing a first embodiment of the present invention.

FIG. 2 is a simplified diagram showing a frequency band of a wireless carrier wave according to the first embodiment of the present invention.

FIG. 3 is a simplified configuration diagram of an adjuster according to the first embodiment of the present invention.

FIG. 4 is a block diagram of a cordless telephone device showing a second embodiment of the present invention.

FIG. 5 is a block diagram of a cordless telephone device showing another embodiment of the second embodiment of the present invention.

[Fig. 6] Fig. 6 is a block diagram of a base station device using a dipole antenna with a circular tube according to a third embodiment of the present invention.

FIG. 7 is a block diagram of a base station device using a discone antenna showing another example of the third embodiment of the present invention.

FIG. 8 is a block diagram of a wireless device showing an embodiment 4 of the present invention.

FIG. 9 is a diagram showing a lapse of communication time between a mobile communication device and a wireless relay device according to Embodiment 4 of the present invention.

FIG. 10 is a block diagram of a conventional wireless device.

FIG. 11 is a simplified diagram showing a frequency band of a wireless carrier wave of a conventional wireless device.

FIG. 12 is a block diagram of a conventional cordless telephone device.

FIG. 13 is a block diagram of a conventional base station device.

[Explanation of symbols]

2 mobile communication device A, 4 mobile communication device B, 6 antenna A, 7 receiver A, 8 transmitter A, 9 antenna duplexer A, 11 control circuit A, 12 antenna B, 13 receiver B, 14 transmitter B , 15 Antenna duplexer B, 17
Control circuit B, 18 wireless repeater, 19 outer conductor A, 2
0 skirt A, 21 skirt B, 22 waterproof ring, 23 duplexer A, 24 regulator A, 25 combiner B, 26 duplexer B, 27 adjuster B, 28 combiner A, 29 control circuit, 31 variable Attenuator A, 32 Variable phase shifter A, 33 Variable attenuator B, 34 Variable phase shifter B,
35 base unit, 36 outdoor relay device, 37 slave unit A, 3
8 line switching circuit, 39 telephone lines, 44 cordless handsets B, 4
5 base station device, 46 winding A, 47 winding B, 48
Coupling capacitor, 49 supply terminal, 50 connection terminal, 5
1 conical ground plate, 52 control lines, 53 wireless repeaters,
54 mobile communication device C, 55 mobile communication device D, 56 antenna C, 58 receiver C, 59 transmitter C, 61 antenna switch, 62 control circuit C, 64 relay switch A,
65 Relay switch B.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hiroyuki Kuroiwa Inventor Hiroyuki Kuroiwa 800 Iwamatsu, Oshima-cho, Nitta-gun Gunma Sanryo Electric Co., Ltd.Gunma Plant (72) Masato Sato Oiwa-machi, Nijima-gun, Nitta-gun 800 Address Sanryo Electric Co., Ltd.Gunma Works (72) Inventor Yasuhiro Ishizaki 2-14-40 Ofuna, Kamakura-shi Living Systems Research Institute, Mitsubishi Electric Corporation (72) Fumiaki Komatsu 2-14-40 Ofuna, Kamakura-shi Mitsubishi (72) Inventor Eiichi Kuroda 2-14-40 Ofuna, Kamakura City Mitsubishi Electric Corporation Life Systems Research Institute

Claims (1)

[Claims] 1. A slave unit which is used at least outdoors, a master unit which is connected to a telephone line and is installed indoors, and an outdoor unit which is connected to this master unit and is provided outdoors to communicate with the slave unit. A relay device and a communication between the slave device and the master device based on an identification signal in a wireless carrier received from the slave device by the outdoor relay device,
Alternatively, a cordless telephone device including a selection unit that selects one of communication between the slave unit and the outside through the telephone line, and a waterproof unit that has a waterproof structure on the outer shell of the outdoor relay device.