JP2001025066A - Cordless communication system, repeater incorporated type phs terminal and communication mode switching method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate the need of subscriber information for a self-supporting PHS terminal (slave unit), to perform an operation as a PHS terminal to a public base station and to perform the operation as a self-supporting PHS master unit to the self-supporting PHS terminal. SOLUTION: This repeater incorporated type PHS terminal 100 receives a frequency for public, performs the operation as a public PHS terminal by a public protocol to the public base station 200 and performs the operation as the self-supporting PHS master unit by a self-supporting protocol to the self-supporting PHS terminal 1. The subscriber information is provided in the repeater incorporated type PHS terminal 100 and the PHS terminal 1 is not provided with the subscriber information. Also, public authentication or the like is performed between the repeater incorporated type PHS terminal 100 and a public network and the PHS terminal 1 is just provided with the self-supporting protocol.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a PHS (Personal H
andy-phone System) Regarding terminal utilization technology,
The present invention relates to a cordless communication system that performs relaying between a public base station and an HS terminal as a slave unit (own terminal), a relay terminal (master unit), and a communication mode switching method.

[0002]

2. Description of the Related Art There is a cordless telephone as a repeater type telephone terminal which operates as a telephone terminal for a public telephone line network and operates as a master terminal for a private terminal (slave).
Also, as shown in FIG. 12, the mobile station receives a public frequency and operates as a public PHS terminal for the public base station 200,
For the self-managed PHS terminal (digital cordless handset) 1, there is a repeater 5 that operates as a self-managed PHS master (digital cordless handset).

[0003] The conventional repeater 5 converts a public protocol into a proprietary protocol and re-radiates it to the PHS terminal 1. However, a new protocol (public protocol) is added to the proprietary protocol to perform authentication and location registration on the PHS terminal side. Was placed. The PHS terminal 1 that communicates via the repeater 5 has the subscriber information (telephone number and other unique information), and authenticates with the public network via the PHS terminal 5 via the repeater 5.
The terminal was doing. Accordingly, the billing is performed not for the repeater 5 but for the telephone number of each PHS terminal 1, and the repeater 5 simply operates as a repeater in relation to the slave unit. In addition, the repeater 5 is usually of a stationary type for home use, and is supplied with power via a home outlet and A / D converted.

[0004]

In the above-mentioned conventional repeater, authentication with the public network is performed on the PHS terminal side via the repeater. Therefore, except for a PHS terminal equipped with a protocol for performing public authentication in its own frequency band. Had a problem that it could not be connected as a slave unit.

[0005] Further, subscriber information (telephone number and other unique information) is required for each slave unit communicating via the repeater and charged for each slave unit.
There was a problem that the burden was heavy. For example, as shown in the example of FIG.
2. When the data-only PHS terminal 1-3 is used as a slave unit, a subscriber contract is required for each slave unit, and a telephone fee is charged for each telephone number.

[0006] The present invention has been made in view of the above-mentioned problems of the conventional repeater, and does not require subscriber information for a self-owned PHS terminal (slave unit), and provides a PHS terminal to a public base station. Operates and owns PHS for self-owned PHS terminals
Cordless communication system, PHS terminal (repeater integrated PHS terminal), and repeater integrated PHS operating as master
It is an object of the present invention to provide a communication mode switching method for a terminal.

[0007]

In order to solve the above problems, a cordless communication system according to a first aspect of the present invention receives a public frequency, converts it to a private frequency, and communicates with a public base station according to a public protocol. A portable repeater that operates as a public terminal, performs self-authentication, and operates as a self-owned parent device using a self-employed frequency using the self-employed frequency is provided.

According to a second aspect of the present invention, in the cordless communication system according to the first aspect, the repeater has subscriber information, and the private terminal does not need the subscriber information.

Further, the repeater-integrated PHS terminal of the third invention receives a public frequency, converts it into a private frequency,
Public PHS for public base stations by public protocol
A relay unit comprising a PS unit that operates as a terminal and performs self-authentication and location registration, and a CS unit that operates as a self-owned PHS master unit by a self-managed protocol using a self-owned frequency for a self-managed PHS terminal. Features.

According to a fourth aspect of the present invention, in the repeater-integrated PHS terminal of the third aspect, the mounting state detecting means for detecting the mounting state with the charger, and the PHS terminal mounted on the charger by the mounting state detecting means. Is detected, the relay operation by the relay unit is enabled, and when not mounted on the charger, the relay operation of the CS unit is not performed so that P
Relay function switching means for enabling a communication operation based on the public protocol by the S unit.

According to a fifth aspect of the present invention, in the repeater-integrated PHS terminal according to the third aspect of the present invention, there is provided mounting state detecting means for detecting a mounting state with the charger, and the PHS terminal is mounted on the charger by the mounting state detecting means. When it is detected that
Relay function switching means for enabling the PS unit to perform communication based on the public protocol by not performing the relay operation of the S unit, and for enabling the relay unit to perform the relay operation when not attached to the charger. It is characterized by having.

A communication mode switching method according to a sixth aspect of the present invention provides a relay device that operates as a public terminal for a public base station using a public protocol and operates as a self-main unit using a self-protocol for a self-operating terminal. In a cordless communication system equipped with a charger, when a repeater is mounted on a charger, self-authentication and location registration by a public protocol with respect to a public base station and execution of a relay operation with a self-protocol with respect to a private terminal are enabled. When the repeater is not attached to the base station, a self-authentication to a public base station by a public protocol and a communication operation based on location registration can be executed.

A communication mode switching method according to a seventh aspect of the present invention is a communication mode switching method comprising: operating a repeater that operates as a public terminal for a public base station according to a public protocol and operates as a self-main unit according to a self-protocol for a self-managed terminal. In a cordless communication system equipped with a relay, when a repeater is mounted on the charger, only a communication operation based on self-authentication and location registration by a public protocol with respect to a public base station can be performed, and the repeater is mounted on the charger. If not, it is possible to perform self-authentication and location registration of the public base station with the public protocol and to perform a relay operation of the private terminal with the private protocol using the private protocol.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS [Outline of Cordless Communication System]
FIG. 1 is an explanatory diagram of a cordless communication system using a repeater-integrated PHS terminal of the present invention.
The terminal 100 receives a public frequency and converts it into a private frequency, operates as a public PHS terminal for the public base station 200 according to a public protocol, and operates a private PHS terminal (digital cordless handset) 1 for a private PHS terminal (digital cordless handset). It operates as a self-managed PHS master (digital cordless master) according to the protocol. That is, as described later, a repeater-integrated PHS
The terminal 100 has, as characteristic features, a PS unit that communicates with the public base station 200 using a public protocol, and a CS unit that communicates with the slave unit (PHS terminal) 1 using a private protocol.

The subscriber information (telephone number, other unique information) is held by the repeater-integrated PHS terminal 100, and the PHS terminal 1, which is a slave, does not have the subscriber information. In addition, for public authentication, etc., the repeater-integrated PHS terminal 100
The PHS terminal 1, which is a slave unit, only needs to have a self-managed protocol, and does not need to have a protocol for performing public authentication and location registration.

Therefore, in the repeater-integrated PHS terminal 100, a public authentication protocol is added when a public protocol is converted into a private protocol and re-radiated as in a conventional repeater (FIGS. 12 and 13). There is no need to use a public protocol for the public base station 200 and a self-owned protocol for the handset 1. In addition, charging is performed for the telephone number of the repeater integrated type 100.

Further, the repeater-integrated PHS terminal 100
In the embodiment, it has the same shape as a commercially available PHS telephone terminal and is portable. When used as a repeater, the battery can be prevented from being consumed by being attached to a charger (charging stand) as described later. When not used as a repeater, it can be used as a normal PHS terminal.

[Outline of Configuration of Repeater-Integrated PHS Terminal] FIG. 2 is a block diagram showing an outline of the configuration of the repeater-integrated terminal, and a portion not shown has the same configuration as the conventional PHS terminal. Good. In FIG. 2, the repeater-integrated PHS terminal 1
00 has a control unit 10, a memory 11, a relay unit 20, a switching unit 30, and a PHS communication unit 40. Note that FIG.
Thus, the configuration without the switching unit 20, ie, the repeater integrated type P
The HS terminal 100 is controlled by the control unit 10, the memory 11, and the relay unit 20.
And a PHS communication unit 40 may be provided. The control unit 10 controls the operation of the entire PHS terminal 100 with the repeater and, when the switching unit 30 is provided, the relay unit based on the attachment detection (detection) signal or the removal detection (detection) signal from the switching unit 30. 20 is controlled. Also, the memory 11
Holds setting values and the like necessary for control by the control unit 10.
The relay unit 20 includes a PS (slave) unit 21 that communicates with the public base station 200 according to a public protocol, and a private CS (master) unit 2 that communicates with the PHS terminal 1 according to a private protocol.
2 is provided. In FIG. 2, the PS unit 21 and the CS unit 2
2 is shown as an independent module, but the PS unit and CS
A part of the unit (for example, RF (wireless communication circuit)) may be shared.

In the case where the switching unit 30 is provided, the relay unit 20 controls the PS unit 21 and C by the control signal from the control unit 10.
The relay operation is performed by the S unit 22 or P
Only the S unit 21 performs communication with the public base station (that is, stops the relay function and performs communication as a PHS terminal).

The switching section 30 comprises a setting section 31 and a mounting state detecting section 32. The setting unit 31 sets a relay function switching pattern for the relay unit 20. When the switching pattern is set by the setting unit 31, a value corresponding to the relay function setting flag in the memory 11 is written. As will be described later, the relay function pattern is a type 1 (on-charge-on) in which the relay function is turned on when the repeater-integrated PHS terminal 100 is mounted on a charging stand (charger) and turned off when the PHS terminal 100 is removed.
(FIGS. 6 to 8) and type 2 (on-charge-off) in which the relay function is turned off when the repeater-integrated PHS terminal 100 is mounted on the charging stand (charger) 110 and turned on when the PHS terminal 100 is removed. ) (FIGS. 9 to 11), the user can set either type 1 or type 2 by selecting a function of the repeater-integrated PHS terminal 100 with a switch or an input key. In addition, type 1 (or type 2)
Standard setting is set so that when the user selects a setting other than the standard setting, the type is set to type 2 (or type 1),
When the setting is released, the setting may return to the standard setting. In the embodiment, the setting unit 31 is provided so that either the type 1 or the type 2 can be selected. However, the relay function may be fixed to the type 1 or the type 2 without providing the setting unit 31.

When the repeater-integrated PHS terminal 100 is mounted on a charging stand (or a charger), the mounting state detecting unit 32 detects (detects) the mounting and detects a mounting detection (detection) signal to the control unit 10. Send out. In addition, the repeater-integrated PHS terminal 10
When 0 is removed from the charging stand (or the charger), it is detected (detected) and a removal detection (detection) signal is sent to the control unit 10. In addition, attachment and detachment to / from a charging stand (or a charger) can be detected by, for example, providing a contact state detection type switch such as a micro switch in a charging plug insertion portion. Further, instead of providing such a switch, a configuration may be adopted in which the rise or fall of the potential due to attachment or detachment is detected.

The PHS communication unit 40 is composed of modules such as a voice input unit 41, a voice output unit 42, a display unit 43, and a key input unit 44. Under the communication control by the PS unit 21, the PHS communication unit 40 operates similarly to an existing PHS terminal. Perform

[Switching of Relay Function] Type 1 (On-Charge-On) FIG. 3 is an explanatory diagram of switching of the relay function of the repeater-integrated PHS terminal when the on-charge is on. When initially set to on-charge-on, the repeater-integrated PHS terminal 10
The relay function of “0” is turned off (OFF).
As shown in (a), the repeater-integrated PHS terminal 100 can perform communication by performing authentication and location registration by a public protocol using a public frequency only with the public base station 200 (that is, ordinary PHS). Communication as a terminal can be performed). Also, as shown in FIG. 3 (b), when placed (attached) on the charging stand 110, the relay function is switched on (ON), and the repeater-integrated PHS terminal 10 is turned on.
0 performs authentication and location registration with the public base station 200 by using a public frequency using a public protocol, and
The terminal performs a function as a repeater between the public base station 200 and the child device 1 by converting a public frequency into a private frequency and performing communication according to a private protocol.
When the repeater-integrated PHS terminal 200 is picked up (removed) from the charging stand 100, the relay function is turned off, and communication similar to that of a normal PHS terminal becomes possible again.

FIG. 4 is a flowchart showing the relay function switching operation when the charging is on.

Step S1: (Relay Function Off) When the value of the relay function function setting flag of the memory 11 means ON / CHARGE ON, the control unit 10 turns off the relay function of the relay unit 20 (the PS unit 22 and the The CS unit 21 is shut off), and the process proceeds to step S2. In addition, repeater integrated type P
This step is omitted when the HS terminal 100 is a model in which only ON / OFF of charging is fixed.

Step S2: (Judgment of presence / absence of attachment detection (detection))
It is checked whether or not a detection (detection) signal of attachment of the S terminal 100 to the charging stand 110 has been received. If the signal has been received, the process proceeds to step S3; otherwise, the attachment detection (detection) has occurred.
The relay function is kept off until a signal is received.

Step S3: (Relay Function ON) When the attachment detection (detection) signal is received in step S2, the control unit 10 sends a relay start instruction signal to the relay unit 20 to enable the relay unit 20 to relay. To

Step S4: (Judgment of presence / absence of removal detection (detection))
It is checked whether or not the removal detection (detection) signal of the S terminal 100 from the charging stand 110 has been received. If it has been received, the process proceeds to step S5. Maintain the enabled state.

Step S5: (Relay function off) When the detachment / attachment detection (detection) signal is received in step S4, the control unit 10 sends a relay end instruction signal to the relay unit 20 and sends the signal to the PS unit of the relay unit 20. And the CS unit 21 are shut off, and the process returns to step S2.

FIG. 5 is an explanatory diagram showing an example of use of the repeater-integrated PHS terminal in the on-charge-on state. With the above configuration, if the repeater-integrated PHS terminal 100 is set to on-charge-on, if the user removes the repeater-integrated PHS terminal 100 from the charging stand 110 and carries it when going out (the relay function is turned off). FIG. 5 (a)
As shown in FIG.
Communication can be performed via the public base station 200 by using the terminal like an HS terminal. In addition, when using the relay function in a house or a business office, when the user returns from home, FIG.
As shown in (b), the relay function is automatically switched on just by placing the repeater-integrated PHS terminal 100 on the charging stand 110, and the operation of manually switching on / off the relay function is not required.

2. Type 2 (On-Charge-Off) FIG. 6 is an explanatory diagram of switching of the relay function of the repeater-integrated PHS terminal in the on-charge-off state. If the initial setting is on-charge / off, the repeater-integrated PHS terminal 10
The relay function of “0” is turned on (ON), and FIG.
As shown in (1), the repeater-integrated PHS terminal 100 performs authentication and location registration using a public frequency with the public base station 200 using a public frequency, and changes the public frequency to a private frequency with a handset (PHS terminal). By performing the conversion and performing communication according to the self-owned protocol, the function as a relay between the public base station 200 and the slave 1 is executed.

Further, as shown in FIG.
When it is put on (attached) to 0, the relay function is turned off (OFF), and the repeater-integrated PHS terminal 100 performs authentication and location registration by the public protocol only with the public base station 200 using the public frequency. Communication can be performed (that is, communication as a normal PHS terminal can be performed).

When the repeater-integrated PHS terminal 100 is picked up from the charging stand 110 (removed), the relay function is switched on (ON). Between them, personal names and locations can be registered by using a public protocol using a public frequency, and communication with a slave unit (PHS terminal) can be performed using a private frequency using a private frequency.

FIG. 7 is a flow chart showing the relay function switching operation when on / off.

Step S1 ': (Relay Function ON) When the value of the relay function setting flag in the memory 11 means ON / CHARGE / OFF, the control unit 10 turns on the relay function of the relay unit 20 (the PS unit 22 and the CS unit 21 is connected), and the process proceeds to step S2 ′. Note that this step is omitted if the repeater-integrated PHS terminal 100 is a model in which only on-charge / off is fixed.

Step S2 ': (Judgment of presence / absence of attachment detection (detection))
It is checked whether or not a detection (detection) signal of mounting of the S terminal 100 to the charging stand 110 has been received. If the signal has been received, the process proceeds to step S3 ′. Keep the function on.

Step S3 ': (Relay function off) When the mounting detection (detection) signal is received in step S2', the control unit 10 sends a relay end instruction signal to the relay unit 20 to send the PS of the relay unit 20. The relay unit is turned off by shutting off the unit 22 and the PS unit 21.

Step S4 ': (Removal detection (detection)
The control unit 10 determines from the mounting state detection unit 32 that the relay-integrated PH
It is checked whether or not a removal detection (detection) signal from the charging stand 110 of the S terminal 100 has been received. If it has been received, the process proceeds to step S5 ′. To maintain.

Step S5 ': (Relay function ON) When the detachment / attachment detection (detection) signal is received in step S4', the control unit 10 sends a relay start instruction signal to the relay unit 20 and The PS unit and the CS unit 21 are connected to enable relaying, and the process returns to step S2.

FIG. 8 is an explanatory diagram showing an example of use of a repeater-integrated PHS terminal in on-charge / off state. With the above-described configuration, when the repeater-integrated PHS terminal 100 is set to on-charge / off, the user does not need to perform the operation in FIG.
As shown in (a), the repeater-integrated terminal 100 is installed in a place where the radio wave condition is good near the window (without being attached to the charging stand 110) to use the relay function.
The battery can be charged by attaching the battery to zero. In this case, when the battery pack is mounted on the charging stand 110, the relay function is automatically switched off, so that the consumption of the battery can be prevented and the charging time can be shortened.

[Application Example of PHS Terminal Integrated with Repeater] Example of Expansion of Indoor Area Using Existing Equipment FIG. 9 is an explanatory diagram of one application example of a PHS terminal with a built-in repeater of the present invention, and is an example of expansion of an indoor area using existing equipment. The communication area in the room can be expanded by connecting the repeater-integrated PHS terminal 100 of the present invention to the existing PHS terminal 1 in the self-service mode. That is, since the existing PHS terminal is permitted to be equipped with a self-owned protocol (not required), the PHS terminal can be used like a cordless telephone handset simply by switching the mode of the PHS terminal to the self-operated mode. Physical PHS terminal 100 and public base station 20
0 can be communicated. Also, when going out, the repeater-integrated PHS terminal can be carried as it is.

2. Example of Connection of Data Dedicated Terminal FIG. 10 is an explanatory diagram of an application example of the repeater-integrated PHS terminal of the present invention, and is an example of connection of a data-only terminal. By connecting the data-dedicated PHS terminal 1 'to the repeater-integrated PHS terminal in the private mode, the data-dedicated PHS terminal 1' can use the public line network without making a public subscription contract. That is, the data-only PHS terminal 1 '
Can be connected to the outside using the telephone number of the repeater-integrated PHS terminal 100.

FIG. 11 is an explanatory view of an application example of the PHS terminal integrated with a repeater according to the present invention, and is an example of expanding use of a transceiver. The PHS terminal can be used as a transceiver in the transceiver mode, but must be registered as a transceiver in the same parent device (that is, the child devices A and B hold the same parent device ID (CSID) while holding the same ID). Need to be). Here, since the repeater-integrated PHS terminal 100 functions as a parent device as described above, FIG.
Transceiver registration becomes possible as shown in FIG. 11A, and transceiver communication becomes possible outdoors, such as outdoors, as shown in FIG. 11B. That is, in the past, since the base unit was conventionally installed in a room such as at home, there was little opportunity to register the transceiver and use it as a transceiver outdoors.
Since it also functions as a master unit, it is expected that the opportunity to use the PHS terminal as a slave unit as a transceiver outdoors will be expanded.

Although the repeater-integrated PHS terminal of the present invention has subscriber information such as a telephone number (stored and stored in a memory), the number of subscriber information is not limited to one. That is, the repeater-integrated PHS terminal can have two or more telephone numbers. For example, if there is only one telephone number, a one-line contract is established. If one PHS terminal is communicating on the slave side, other PHS terminals cannot communicate, but if two telephone numbers are provided, two lines can be used. So two at the child machine side
One PHS terminal can communicate. Similarly, three or more pieces of subscriber information can be held by the repeater-integrated PHS terminal, and the slave unit can perform the same communication by the number corresponding to the telephone number of the repeater-integrated PHS terminal. .

Although one embodiment and several application examples of the present invention have been described above, the present invention is not limited to the above-described embodiments and application examples, and it goes without saying that various modifications can be made. Absent.

[0046]

As described above, according to the present invention, a repeater (a PHS terminal with a built-in repeater) can communicate with a slave unit using only a proprietary protocol. The terminal can be used as a slave.

Also, since the subscriber information is held in the repeater (PHS terminal with integrated repeater), and the slave unit does not need to have the subscriber information, billing is performed with the repeater having a telephone number (PHS with integrated repeater). Terminal), and the burden on the user (contract initial cost and basic fee) is reduced. In addition, even when the data-only terminal is used as a slave unit, communication can be performed with the data-only terminal without a telephone number (subscriber information), thereby reducing the burden on the user.

Also, a repeater (a PHS terminal integrated with a repeater)
Since it has a function as a master unit, it is possible to register a transceiver, and since it is portable, it is expected that the number of machines using the transceiver outdoors or the like of the slave unit will increase.

Also, the repeater-integrated PHS terminal can automatically switch between a mode that can be used as a PHS terminal and a mode that can be used as a repeater, depending on the state of attachment to the charger. The operability in use has been improved without the need.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a cordless communication system using a repeater-integrated PHS terminal of the present invention.

FIG. 2 is a block diagram illustrating an outline of a configuration of a repeater-integrated terminal.

Fig. 3 Repeater-integrated PHS with on-charge-on
It is explanatory drawing of the relay function switching of a terminal.

FIG. 4 is a flowchart showing a relay function switching operation when on-charge-on.

FIG. 5: Repeater-integrated PHS with on-charge-on
It is an explanatory view showing an example of use of a terminal.

FIG. 6 is an explanatory diagram of switching of a relay function of a repeater-integrated PHS terminal during on-charge / off.

FIG. 7 is a flowchart showing a relay function switching operation when on / charge / off.

FIG. 8: Repeater-integrated PHS with on-charge off
It is an explanatory view showing an example of use of a terminal.

FIG. 9 is an explanatory diagram of an application example of a PHS terminal with a built-in repeater of the present invention.

FIG. 10 is an explanatory diagram of an application example of a repeater-integrated PHS terminal of the present invention.

FIG. 11 is an explanatory diagram of an application example of the repeater-integrated PHS terminal of the present invention.

FIG. 12 is an explanatory diagram showing features of a relay function of a conventional indoor repeater.

FIG. 13 is an explanatory diagram of a PHS terminal (slave) connected to a conventional indoor repeater.

[Explanation of symbols]

 1 PHS terminal (Private terminal) 1 'PHS terminal dedicated to data (Private terminal) 10 Control unit (Relay function switching means) 20 Relay unit 21 PS unit 22 Private CS unit (CS unit) 30 Switching unit (Relay function switching means) 32 Attachment state detection unit (attachment state detection means) 100 Repeater-integrated PHS terminal (self-owned parent device, repeater) 200 Public base station

Continued on the front page F term (reference) 5K027 AA12 BB01 CC08 GG04 HH22 HH24 KK03 5K067 AA22 AA41 BB04 DD13 DD16 DD57 EE03 EE04 EE06 EE10 FF13 GG01 GG11 HH05 HH13 HH24 KK06 KK17

Claims (7)

[Claims] 1. A public-use frequency is received and converted into a private-use frequency. The public-use base station operates as a public-terminal according to a public protocol and performs self-authentication. A cordless communication system comprising: a portable repeater that operates as a self-owned parent device according to a self-managed protocol by using a personal computer. 2. The cordless communication system according to claim 1, wherein said repeater has subscriber information, and said private terminal does not require subscriber information. 3. A PS unit for receiving a public frequency and converting it to a private frequency, operating as a public PHS terminal by a public protocol for a public base station, and performing self-authentication and location registration with a private PHS terminal. A relay unit comprising a CS unit operating as a self-managed PHS master according to a self-management protocol using the self-management frequency. 4. A mounting state detecting means for detecting a mounting state with the charger, and when the mounting state detecting means detects that the charger is mounted on the charger, a relay operation by the relay unit is enabled. And a relay function switching unit that disables the relay operation of the CS unit when the battery pack is not mounted on the charger and enables a communication operation based on a public protocol by the PS unit. The repeater-integrated PHS terminal according to claim 3. 5. A mounting state detecting means for detecting a mounting state with a charger, and when the mounting state detecting means detects that the charger has been mounted, the relay operation of the CS unit is not performed. Relay function switching means for enabling communication based on a public protocol by the PS unit, and enabling the relay unit to perform a relay operation when the charger is not attached to the charger. The repeater-integrated PHS terminal according to claim 3. 6. A cordless communication system including a repeater that operates as a public terminal for a public base station using a public protocol and operates as a self-main unit according to a self-owned protocol for a self-managed terminal. When the repeater is mounted, a self-authentication for a public base station by a public protocol and a communication operation based on location registration can be executed, and a self-protocol for a self-operated terminal can be performed by a self-protocol operation. A communication operation based on a public protocol for a public base station and a communication operation based on location registration when the repeater is not mounted on the communication base station. 7. A cordless communication system including a relay that operates as a public terminal according to a public protocol for a public base station and operates as an independent master device according to an independent protocol for an independent terminal. When the repeater is mounted, only a communication operation based on self-authentication and location registration by a public protocol for a public base station can be performed, and when the repeater is not mounted on the charger, the public base station A self-authentication and location registration by a public protocol with respect to the private terminal and a relay operation by a private protocol to a private terminal.