Radio telephone system control apparatus and method

A method and apparatus for controlling a radio telephone system of the type wherein a connection between a wired telephone channel and a plurality of radio telephone handsets is controlled by a single base station connected to the wired telephone channel, a ring signal through the wired telephone channel is detected, a paging signal is sent to the radio telephone handsets from the base station when the ring signal is detected and a paging response signal is sent to the base station from the radio telephone handset in response to the paging signal. Further a channel designating signal is sent to the radio telephone handset in accordance with the paging response signal, a radio channel of the base station is switched to a radio channel corresponding to the channel designating signal, the radio channel of the radio telephone handset is switched to a radio channel corresponding to the channel designating signal, and a speech channel is established between a radio telephone handset responding to the paging signal and the wired telephone channel.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to a radio telephone system control apparatus and a 
method for controlling the connection of a base station connected to wired 
telephone channel and a plurality of radio telephone handsets connected to 
the base station through radio channels with the base station, and more 
particularly an apparatus for controlling the connection in response to a 
ring signal made through lines for wired telephone sets. 
2. Description of the Related Arts 
Radio-telephone systems comprise a base station connected to wired 
telephone channels and one or more radio telephone handsets connected to 
the base station through radio channels, such as a cordless telephone. The 
cordless telephone apparatus consists of a base station connecting 
apparatus connected to wired telephone channels, and a radio telephone 
handset provided for the base station in a one to one correspondence, and 
the frequencies of its signals are fixed such that up radio channels from 
the radio telephone handsets to the base station utilize signals of 
frequency f.sub.1, while down telephone channels from the base station to 
the radio telephone handsets utilize signals of frequency f.sub.2. As a 
consequence, where two radio telephone handsets are utilized, it is 
necessary to install two base stations. 
With such a radio telephone system utilizing two radio telephone handsets 
and two base stations, however, two radio telephone handsets are not 
usually used simultaneously, so that provision of two base stations is not 
economical. 
In recent years, for the purpose of efficiently utilizing allocated 
frequencies, a so-called multi-channel access system has been adopted 
wherein a frequency being used is determined by utilizing a common 
channel, for example, a control channel between a plurality of base 
stations, and then the channel is switched to a speech channel 
corresponding to the frequency. However, when such multi-channel access 
system is adopted, there is a problem in the case where a base station is 
provided for each of the two radio telephone handsets that when a ring 
signal is received from a wired telephone set, the two base stations start 
connection control using respective control channels simultaneously, 
whereby radio waves from these control channels interfere with each other. 
Thus, the connection control is sometimes made impossible. 
SUMMARY OF THE INVENTION 
It is therefore an object of this invention to provide a radio telephone 
system control apparatus and a method which enables a connection control 
for a plurality of radio telephone sets with a single base station as well 
as transferring from a radio telephone handset in which a voice channel 
exists to other radio telephone sets. 
According to one aspect of this invention, there is provided a radio 
telephone system control apparatus comprising a plurality of radio 
telephone handsets, each having a handset transceiver; a base station 
connected to a wired telephone channel for exchanging signals between the 
base station and the handset transceivers of said telephone handsets; 
means provided for said base station for detecting a ring signal through 
said wired telephone channel; means for sequentially sending, with a 
predetermined time difference, paging signals each containing a channel 
designating signal to the handset transceivers of said plurality of radio 
telephone handsets from the base station transceiver of said base station 
when said paging is detected; means responsive to the received paging 
signal for sending a paging response signal to the base station 
transceiver of said base station from the handset transceiver handsets of 
said radio telephone sets, and for switching the radio channel of the 
handset transceivers of said radio telephone handsets to a radio channel 
corresponding to said channel designating signal; means for switching the 
radio channel of said base station transceiver of said base station to a 
radio channel corresponding to said channel designating signal when said 
paging response signal is received within a predetermined interval after 
sending out said paging signal from the base station transceiver of said 
base station. 
Whereby the connection control between said wired telephone channel and 
either one of said plurality of radio telephone handsets based on the ring 
signal on said wired telephone channel is effected by a single base 
station. 
According to a modified embodiment of this invention, there is provided a 
radio telephone system control apparatus comprising a plurality of radio 
telephone handsets, each having a handset transceiver; base station 
connected to a wired telephone channel for exchanging signals between the 
base station and the handset transceivers of said radio telephone 
handsets; means provided for said base station for detecting a ring signal 
through said wired telephone channel; means for sending a paging signal to 
the handset transceivers of said radio telephone handsets from the base 
station transceiver of said base station when said paging is detected by 
said detecting means; means for sending a paging response signal to the 
base station radio set of said base station from the handset transceiver 
of said radio telephone handset in response to said paging signal; means 
responsive to said paging response signal for sending a channel 
designating signal to the handset transceiver of said radio telephone 
handset from the base station transceiver of said base station; means for 
switching the radio channel of the base station transceiver of said base 
station to a radio channel corresponding to said channel designating 
signal; means responsive to said channel designating signal for switching 
a radio channel of the handset transceiver of said radio telephone set to 
a radio channel corresponding to said channel designating signal, thereby 
effecting connection control between said wired telephone channel and 
either one of said plurality of radio telephone handsets based on the 
paging through said wired telephone channel with a single base station. 
According to another embodiment of this invention, there is provided radio 
telephone system control apparatus comprising a plurality of radio 
telephone handsets, each having a handset transceiver; base station 
connected to a wired telephone channel for exchanging signals between the 
handset transceivers of said radio telephone handset and said base 
station; means responsive to a predetermined transfer operation for 
sending a transfer address designation signal to the base station 
transceiver of said base station from a handset transceiver of said radio 
telephone handset subjected to a transfer operation; means responsive to a 
reception of said transfer address designating signal for sending a paging 
signal to the handset transceiver of an addressed radio telephone handset 
from the base station transceiver of said base station; means responsive 
to the receipt of said paging signal for sending a paging response signal 
to the base station transceiver of said base station from the handset 
transceiver of said transfer addressed radio telephone set; means 
responsive to the receipt of said paging response signal for sending a 
bell ringing signal to the handset transceiver of said radio telephone 
handset from the base station transceiver of said base station; means 
provided for said radio telephone handset for producing a call tone for 
sending an off-hook signal to the radio telephone handset of said base 
station from the handset transceiver of said transfer addressed radio 
telephone handset when said transfer addressed radio telephone handset 
goes off hook; and means responsive to said off-hook signal for the 
handset transceiver of a radio telephone handset which has issued a 
transfer signal from the base station to said master apparatus, thereby 
substituting said radio telephone handset which has issued said transfer 
signal with said wired telephone channel and said transfer address radio 
telephone handset which has sent out said off-hook signal. 
According to another aspect of this invention, there is provided a method 
of controlling a radio telephone system of the type wherein the connection 
of a wired telephone channel and a plurality of radio telephone handsets 
is controlled by a single base station connected to said wired telephone 
channel, said method comprising the steps of; detecting a ring signal on 
the wired telephone set; sequentially sending, with a predetermined time 
difference, a paging signal to said plurality of radio telephone handsets 
from said base station when said paging is detected; connecting a radio 
channel of said master channel and a radio channel of said radio channel 
to the same channel when either one of said radio telephone handsets 
respond to said paging signal; and establishing a speech channel between a 
radio telephone handset responding to said paging signal and a wired 
telephone channel connected to said base station. 
According to a modification, there is provided a method of controlling a 
radio telephone system of the type wherein a connection between a wired 
telephone channel and a plurality of radio telephone handsets is 
controlled by a single base station connected to said wired telephone 
channel, said method comprising the steps of: detecting a ring signal on 
said wired telephone channel; sending a paging signal to said radio 
telephone handset from said base station when said ring signal is 
detected; sending a paging response signal to said base station from said 
radio telephone handset in response to said paging signal; sending a 
channel designating signal to said radio telephone handset from said base 
station in response to said paging response signal; switching a radio 
channel of said base station to a radio channel corresponding to said 
channel designating signal; switching a radio channel of said radio 
telephone handset to a radio channel corresponding to said channel 
designating signal in response to said channel designating signal; and 
establishing a speech channel between a radio telephone handset responding 
to said paging signal and said wired telephone channel connected to said 
base station. 
According to another modification, there is provided a radio telephone 
system control method of the type wherein a connection between a wired 
telephone channel and a plurality of radio telephone handsets is 
controlled by a single base station, said method comprising the steps of: 
sending a transfer address designating signal to the base station 
transceiver of said base station from a radio telephone handset which has 
sent out a transfer signal in response to a predetermined transfer 
operation; sending a paging signal to a transfer address radio telephone 
handset from said base station when said transfer address designating 
signal is received; sending a paging response signal to the base station 
transceiver of said base station from said transfer address radio 
telephone handset when said paging signal is received; and connecting the 
transfer address telephone handset responsive to said paging signal to 
said wired telephone channel connected to said base station instead of a 
radio telephone handset which has operated to send a transfer signal.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
A preferred embodiment of the radio telephone system according to this 
invention shown in FIG. 1 comprises one base station 4 and two radio 
telephone handsets 5 and 5'. For the purpose of simplifying the 
description, only two radio telephone handsets are shown but it will be 
clear that the invention is also applicable to three or more radio 
telephone handsets. The base station 4 is connected to a wired telephone 
channel, not shown, through a terminal 3. A signal from the wired 
telephone channel inputted to terminal 3 is supplied to a transmitter 16 
via a line relay 23 and a hybrid circuit 22, while the output from the 
transmitter 16 is sent out from an antenna 12 via an antenna duplexer 13. 
On the other hand, a signal received by antenna 12 is applied to a 
receiver 14 through antenna duplexer 13, and the output from the receiver 
14 is supplied to the wired telephone channel via hybrid circuit 22, line 
relay 23 and terminal 3. A synthesizer 21 is provided for determining the 
radio frequency of the transmitter 16 and the receiver 14, and a control 
unit 15 is provided for the purpose of controlling transmitter 16, 
receiver 14 and synthesizer 21. Read only memory devices (ROM) 18 and 18' 
are provided for the purpose of storing identification information for 
controlling the connections to radio telephone sets to be described later, 
the identification information being used in the control unit 15. 
The radio telephone handsets 5 and 5' are connected to the base station 
through radio channels. The radio telephone handsets 5 and 5' have the 
same construction except that their ROMs 17 and 17' store different 
information. More particularly, element 6 bounded by dotted lines in FIG. 
1 has the same construction for radio telephone handsets 5 and 5' so that 
in the following description, elements utilized in radio telephone handset 
5' are designated by the same reference numberals as those used in the 
radio telephone handset 5 except addition of a prime. The signal 
transmitted from the base station is received by an antenna 11 and applied 
to a receiver 19 through an antenna duplexer 10, and the output of the 
receiver 19 is supplied to a handset or loudspeaker 29 to be connected to 
generate sound. An input signal to a microphone 30 is sent to the base 
station 4 via transmitter 8, antenna duplexer 10, and antenna 11. A 
synthesizer 20 is provided for determining the radio frequency of receiver 
19 and transmitter 8, while a control unit 9 is provided for controlling 
receiver 19, transmitter 8 and synthesizer 20. A loudspeaker 31 connected 
to the synthesizer produces a call tone. A hook switch 7 is provided to 
effect an origination and to respond to the call tone produced by the 
loudspeaker 31. 
The information stored in ROMs 17 and 17' corresponds to that stored in 
ROMs 18 and 18' of the base station 4. 
This embodiment employs a multichannel access system comprising a single 
control channel (C-CH) and a plurality, for example 45, of speech 
channels. Thus a speech channel is established by commonly utilizing a 
single control channel by a plurality of apparatus. The operation of this 
embodiment will be described with reference to the flow charts shown in 
FIGS. 2 through 6. 
FIG. 2 shows a flow chart for the case when radio telephone handset 5 
originates a call. At step 201, when the hook switch 7 of the radio 
telephone handset 5 is hooked off at step 202, this state change is 
detected by control unit 9 and this unit 9 turns ON the transmitter 8, and 
then at step 203 the originating signal is sent to the base station 4 via 
antenna duplexer 10 and antenna 11. The transmission of the originating 
signal from the radio telephone set 5 to the master apparatus 4 is made by 
using the control channel (C-CH). Upon termination of the transmission of 
the originating signal, at step 204, the control unit 9 turns off the 
transmitter 8. At step 205, the base station 4 receives with receiver 14 
the originating signal via antenna 12 and antenna duplexer 13 and the 
demodulated output from the receiver 14 is applied to the control unit 15. 
Then at step 206, the control unit 15 turns ON transmitter 16 for 
transmitting a call signal to radio telephone handset 5' at step 207. The 
transmission of the call signal from the master apparatus 4 to the radio 
telephone handset 5' is performed by using the control channel (C-CH). For 
the purpose of selectively sending the call signal to the radio telephone 
handset 5', an identifying information is incorporated into the call 
signal stored in the ROM 18'. When the radio telephone handset 5' receives 
the call signal, it compares the identifying signal contained in the call 
signal with the information stored in ROM 17', and when they coincide with 
each other, the radio telephone handset 5' accepts the call signal. In the 
following, a digit `2` shows a signal containing the identifying signal 
stored in ROM 18', while a digit `1` shows a signal containing an 
identifying signal stored in ROM 18. An identifying signal stored in ROMs 
18, 18', 17 and 17' is made up of a identifying code common to both radio 
telephone handset 5 and 5' and individual identifying codes assigned to 
respective radio telephone handset 5 and 5'. The common identifying code 
is used to identify the other radio telephone handset. 
At step 208, the radio telephone handset 5' receives a call signal 2 
transmitted from the base station 4 by receiver 19' through antenna 11' 
and antenna duplexer 10'. The demodulated output from receiver 19' is 
supplied to control unit 9' whereby it turns ON transmitter 8' at step 
209, and a call response signal 2 is sent to the base station 4 at step 
210. As has been pointed out before, the call response signal 2 contains 
an identifying signal stored in ROM 17'. Upon termination of the call 
response signal 2, at step 211, the control unit 9' of the radio telephone 
handset 5' turns OFF transmitter 8'. 
After sending the call signal 2 at step 207, at step 212 the master 
apparatus 4 executes a judgment as to whether a predetermined time has 
elapsed or not. When the result of judgment shows that the predetermined 
time has not yet elapsed, that is, a time out has not occurred, the 
program is transferred to step 213 at which a judgment is made as to 
whether receiver 14 has received a call response signal 2 from radio 
telephone handset 5' or not. When the result of judgment at step 213 is 
NO, the program is returned to step 312. When result of judgment at step 
212 shows a time out and when the result of judgment at step 213 shows 
receipt of a call response signal 2, the program is transferred to step 
214. More particularly, when a predetermined time has elapsed after 
sending out a call signal 2 from the base station 4, or when a call 
response signal 2 is received from radio telephone handset 5', the program 
is transferred to step 214. 
At step 214, a channel designating signal 1 for designating a predetermined 
channel is transmitted to radio telephone handset 5 by using the control 
channel. At step 215, the radio telephone handset 5 executes a judgment as 
to whether the radio telephone handset 5 has received the channel 
designating signal 1 or not. When the result of judgment is YES, the 
control unit 9 controls the synthesizer 20 for switching the radio 
frequency of transmitter 8 and receiver 19 to that corresponding to a 
predetermined speech channel (S-CH.sub.1) at step 216. After that, at step 
217 a timer is operated and after a predetermined time, the transmitter 8 
is turned ON at step 218. 
Following the transmission of the channel designating signal at step 214, 
at step 219, base station 4 sends out a channel designating signal 2 to 
radio telephone handset 5' by using the control channel. The channel 
designating signal 2 designates the same speech channel as the channel 
designating signal 1. Upon completion of the transmission of the channel 
designating signal, at step 220, the master apparatus 4 turns OFF 
transmitter 16 so as to control the synthesizer 21, thereby switching the 
transmission/reception frequency to that corresponding to speech channel 
(S-CH.sub.1) and the turning ON transmitter 16 at step 222. As a 
consequence, speech between the base station and the radio telephone 
handset 5 becomes possible by utilizing the speech channel (S-CH.sub.1). 
At step 223, in radio telephone handset 5' a judgment is made as to whether 
the channel designating signal 2 sent from the base station 4 has been 
received or not. When the result of judgment executed at step 223 is YES, 
the program is advanced to step 224 at which the transmission/reception 
frequency is switched to that corresponding to speech channel (S-CH.sub.1) 
and at step 225, the state is changed to a waiting state. Under this state 
since the transmitter 8' at the radio telephone handset 5' is OFF, the 
radio telephone handset 5' can receive only a signal from the base station 
4 utilizing speech channel (S-CH.sub.1). 
After turning ON the receiver 8 at step 218, the radio telephone set 5 
turns ON the audio frequency circuit of the transmitter 8 and receiver 19 
at step 226. At step 222, the base station turns ON transmitter 16 and 
turns ON line relay 23 at step 227 for closing a relay contact, whereby 
radio telephone handset 5 can communicate speech through a wired telephone 
channel connected to terminal 3 of the base station 4 by using a speaker 
29 and microphone 30. In this state, when the hook switch 7' of the radio 
telephone handset 5' now in the waiting state is hooked OFF, the reception 
of speech is possible but transmission is impossible. 
The operation of a case wherein a ring signal is received by the base 
station from the wired telephone channel will be described as follows. 
FIG. 3 shows a flow chart showing the operation of a case in which a ring 
signal is received by the base station from a wired telephone channel. The 
detection of the ring signal is made by judging the presence or absence of 
the ring signal by the control unit 15 based on the output signal of a 
detecting circuit, not shown, connected to the wired telephone channel. At 
step 301, when a ring signal is received by the master apparatus, in other 
words, when the base station is called by the wired telephone channel, at 
step 302 the base station turns ON the transmitter 16 so as to send out a 
paging signal containing a designating signal that designates a 
predetermined speech channel at step 303. Paging signals are sent to 
respective radio telephone sets in a predetermined order of priority which 
is determined by the order of inserting IC sockets into ROMs 18 and 18' or 
by the order of information prestored in ROMs 18 and 18'. The order of 
priority may be set by an independent switch or the like, or may be 
randomly set by generating a suitable random number. Further, the order of 
priority can be set according to the hysteresis of the connection to the 
wired telephone channel. Thus, for example, the most recently used radio 
telephone handset or the radio telephone set most frequently used can be 
set to the highest priority. 
In the flow chart shown in FIG. 3, the radio telephone handset 5 is a 
higher order of priority than the radio telephone handset 5'. Thus, at 
step 303, a paging signal 1 is sent to radio telephone handset 5. At step 
304, when the radio telephone handset 5 receives the paging signal 1, 
transmitter 8 is turned ON at step 305, and a paging response signal 1 is 
sent to the base station at step 306. 
The base station 4 monitors the paging response signal 1. When the paging 
signal is received within a predetermined interval after sending out the 
paging signal 1 at step 303, or more particularly, at step 307, when it is 
judged that there is no time out, and at step 308, when it is judged that 
the paging response signal 1 has been received, the program is transferred 
to step 309 for turning OFF receiver 16. Then at step 310, a radio channel 
is switched to a speech channel (S-CH.sub.2). After that at step 311, the 
transmitter 16 is turned ON. 
At step 306, upon termination of the transmission of the paging response 
signal 1, at step 312, the radio telephone handset 5 turns OFF transmitter 
8 to switch the radio channel to the speech channel (S-CH.sub.2). After 
that, at step 314, transmitter 8 is turned ON again, thereby establishing 
a speech channel between base station 4 and radio telephone handset 5 by 
utilizing the speech channel (S-CH.sub.2). 
At step 311, base station turns ON transmitter 16 and then at step 315, 
base station sends out a bell ringing signal by using the speech channel 
(S-CH.sub.2). At step 319 as the radio telephone handset 5 receives the 
bell ringing signal, at step 320, call tone is produced from loudspeaker 
31. At step 318 when the hook switch 7 is hooked off in response to the 
call tone, at step 321, an off-hook signal is sent to base station 4 
through the speech channel (S-CH.sub.2). Then at step 322, the audio 
frequency circuit is turned ON. 
At step 316 when base station 4 receives the off-hook signal from radio 
telephone handset 5, at step 317, the line relay 23 is turned ON, whereby 
the radio telephone handset 5 can exchange speech with a wired telephone 
channel through the base station 4. 
At step 307, when time out is judged, that is where a paging response 
signal 1 is not returned from the radio telephone handset 5 after elapse 
of a predetermined interval, after sending out of the paging signal, at 
step 323 a paging signal 2 for the radio telephone handset at the next 
level of priority is sent out. At step 324, when the radio telephone 
handset 5' receives the paging signal 2, at step 325, the transmitter 8' 
is turned ON to send out the paging response signal 2 at step 326. When 
this paging response signal 2 is received by the base station 4 within a 
predetermined interval after sending out the paging signal 2, the program 
is transferred to step 309 at which the transmitter 16 is turned OFF, and 
then the channel is switched to speech channel (S-CH.sub.2), whereby the 
transmitter 16 is turned ON again to send out a bell ringing signal at 
step 315. 
After sending out the paging response signal 2, the radio telephone handset 
5' executes the same operations as the radio telephone handset 5 with 
respect to a portion 24 of the flow chart bounded by dotted lines. More 
particularly, transmitter 8' is turned OFF first for switching the speech 
channel (S-CH.sub.2) and turning ON again the transmitter 8'. When a bell 
ringing signal is received from the base station, a call tone is sent out. 
When the hook switch 7' is taken off-hook in response to the call tone, an 
off-hook signal is sent out and then the audio frequency circuit is turned 
ON. 
At step 316, when the base station receives an off-hook signal from radio 
telephone handset 5', at step 317, the line relay is turned ON so as to 
connect the radio telephone handset 5' to the wired telephone channel via 
the master apparatus. 
When the time out is judged at step 327, that is when no paging response 
signal 2 is sent back from radio telephone handset in a predetermined 
interval even though a paging signal 2 has been sent out, the program is 
transferred to step 329, thus bringing the base station to the waiting 
state. 
FIG. 4 shows another flow chart in a case where a ring signal is received 
by the base station from a wired telephone channel. As can be noted from 
this flow chart, radio telephone handsets 5 and 5' intermittently receive 
signals at different periods and the base station sends a paging signal 
containing only the common identifying code. When either one of the radio 
telephone handsets 5 and 5' (in the flow chart telephone handset 5') 
respond to the paging signal, both radio telephone handsets 5 and 5' are 
connected to the predetermined speech channel (S-CH.sub.2) so as to cause 
the telephone handset 5' to generate a call tone and the telephone handset 
5', which went off-hook in response to the call tone, is connected to the 
wired telephone channel, whereas the radio telephone handset 5 is brought 
to the waiting state. 
At step 401 when there is a call from the wired channel, at step 402, the 
base station 4 turns ON transmitter 16 for transmitting a paging signal 
over the control channel (C-CH) at step 403. As above described, the 
paging signal contains only the common identifying code. 
In a condition when radio telephone handsets 5 and 5' do not receive any 
signal, they intermittently receive the signal at a predetermined period 
(battery saving operation). More particularly, at step 404, radio 
telephone set 5 turns OFF receiver 19 and as the set time of the timer 1 
elapses it turns ON receiver 19 at step 405. On the other hand, at step 
407 where there is no received signal and the set time of timer 2 has 
elapsed at step 408, the receiver 19 is turned OFF again. In the same 
manner, at step 409 radio telephone handset 5' turns OFF receiver 19'; and 
as the set time of time 3 has elapsed at step 410, the receiver 19' is 
turned ON. At step 412 where there is no signal received, and at step 413 
the set time of timer 4 has elapsed, the receiver 19' is turned OFF again. 
Suppose now that a paging signal transmitted from base station 4 at step 
403 is received by radio telephone handset 5' and that the reception is 
judged at step 412. In this case, the program is transferred to step 414 
so as to make a judgment as to whether the received signal is a paging 
signal or not. When the signal is the paging signal, at step 415, 
transmitter 8' is turned ON for sending out a paging response signal at 
step 416 and for turning OFF the transmitter 417 at step 417. When the 
paging response signal is received by the base station 4 at step 419 in a 
predetermined interval after sending out the paging signal at step 403, 
the base station 4 sends out a channel designating signal that designates 
a predetermined speech channel at step 420. After that, at step 421, 
transmitter 16 is turned OFF. When the radio telephone handset 5 receives 
the channel designating signal at step 423 in a predetermined interval 
after sending out the paging response signal at step 416, and when the 
received signal is judged as the channel designating signal at step 422, 
the program is transferred to the flow chart shown by dotted line block 
24. This flow chart is the same as the flow chart in block 24 shown in 
FIG. 3. 
At step 407, the channel designating signal transmitted from the base 
station 4 is judged by radio telephone handset 5, and then the program is 
transferred to step 424. In this case, since the signal is not the paging 
signal, after switching the channel to speech channel (S-CH.sub.3) at step 
425, and the radio telephone handset is brought the waiting state at step 
426. 
At step 421, after turning OFF transmitter 16, the base station switches 
the channel to the speech channel (S-CH.sub.3) at step 427 and then the 
program is transferred to the flow chart shown by block 25. The flow chart 
shown by this block 25 is the flow chart shown by block 25 in FIG. 3. In 
FIG. 4, two flow charts shown by each of blocks 26 and 27 are the same, 
respectively. 
FIG. 5 shows a flow chart where a ring signal is received from the wired 
telephone channel. The flow chart shown in FIG. 6 is a flow chart after 
the master apparatus 4 and the radio telephone handsets 5 and 5' are 
connected to the same speech channel in the same manner as the flow chart 
shown in FIG. 4. At step 501, the base station 4 judges as to whether 
there is a ring signal from the wired telephone channel. When it is judged 
that there is a ring signal, at step 502, a bell ringing signal is sent 
out, whereas when it is judged that there is no ring signal, at step 503, 
a bell non-ringing signal is sent out. Whether the bell ringing signal is 
received or not is judged by radio telephone handset 5, for example at 
step 504. 
At step 505, when it is judged that the received signal is the bell ringing 
signal, a call tone signal is sent out at step 506, and the hook switch 7 
is hooked OFF at step 507 in response to the call tone. Then, transmitter 
8 is turned ON at step 508 to send out an off-hook signal at step 509 
which is received by base station 4 at step 510, whereby the base station 
4 turns ON the line relay 23 at step 511. At step 509, after sending out 
the off-hook signal, the radio telephone handset 5 turns ON the audio 
frequency circuit at step 512, thus establishing a speech state at step 
513. 
At step 505, when it is judged that the bell ringing signal is not 
received, and at step 507, when it is judged that the hook switch is ON at 
step 507, that is when it is judged that the hook switch is not OFF, the 
program is returned to step 504. At step 510, when it is judged that an 
OFF hook signal is not yet received, the program is returned to step 501. 
At step 504, when it is judged that no signal is received, the program is 
returned to step 514 to bring the state to the waiting state. More 
particularly, with the flow chart shown in FIG. 5, when there is a ring 
signal through a wired telephone channel, both radio telephone handsets 5 
and 5' generate a call tone signal so that the radio telephone handset 
first taken off hook establishes a speech channel, while the other radio 
telephone handset goes to a waiting state because there is no signal 
received. In this case, by using only the bell ringing signal the circuit 
is put in a waiting state when the bell ringing signal does not arrive for 
a predetermined interval. 
FIG. 6 shows radio telephone period transfer operations of the radio 
telephone system according to this invention. Suppose now that radio 
telephone handset 5 is talking whereas the radio telephone handset 5' is 
in the waiting state. Under these states, when transfer switch 32 of the 
radio telephone handset 5 is turned ON, at step 601 it is judged that 
there is a transfer request so that at step 602, the radio telephone 
handset 5 sends out a signal 2 (connecting signal) designating a radio 
telephone handset to which the radio telephone period is to be transferred 
(herein after turned a transfer address). It should be understood that the 
transfer address designation signal contains information that identifies 
radio telephone handset 5', that is, the transfer address. At step 603, 
when base station 4 receives the transfer address signal 2, the program is 
transferred to step 604 for placing the office line on hold. Then at step 
605, a paging signal 2 is sent to radio telephone handset 5' to which the 
transfer is to be made by using a speech channel (S-CH.sub.1). 
At step 607, when the radio telephone handset 5' receives the paging signal 
2, the program is transferred to step 608 at which transmitter 8' is 
turned ON. Then at step 609, the paging response signal 2 is sent back to 
the base station 4 through speech channel (S-CH.sub.1). At step 610, the 
base station detects the paging response signal 2 from the radio telephone 
handset 5' and then at step 611, a bell ringing signal 2 is sent to the 
radio telephone handset 5' through speech channel S-CH.sub.1. 
At step 612, when the radio telephone handset 5' detects the reception of 
the bell ringing signal 2, it sends out a call tone signal at step 613. 
When the telephone handset of a called party goes to an off-hook state at 
step 614, the program is transferred to step 615 at which an off-hook 
signal is sent to the base station through speech channel (S-CH.sub.1). 
Then at step 616, the audio frequency circuit of receiver 19' is turned 
ON. 
At step 617, when the base station 4 detects the receipt of the off-hook 
signal from the radio telephone handset 5', at step 617 a transfer 
termination signal 1 is sent to radio telephone handset through the speech 
channel (S-CH.sub.1). 
At step 602, after the radio telephone handset 5 sends out a transfer 
address signal 2, and then at step 619, transmitter 8' is turned ON. Then 
at step 620, a transfer lamp 33 is lighted to inform that the signal is 
now being transferred. At step 621, when radio telephone handset 5 detects 
the transfer termination signal 1 sent from the base station 4, at step 
622, the transfer lamp is extinguished. Then the program is transferred to 
step 622 to extinguish the transfer lamp 33, and at step 623, the state is 
brought to the waiting state. 
At step 618, after the base station 4 has transmitted the transfer 
termination signal 1, the hold of the in-use office line is released at 
step 624, thus completing the transfer of the signal from radio telephone 
handset 5 to radio telephone handset 5' to enable radio telephone handset 
5' to speak. 
Although the embodiment shown in FIG. 6 is constructed such that the base 
station 4 waits to operate until a paging response signal from the 
transfer address radio telephone apparatus, that is, the radio telephone 
handset 5', and an off-hook signal 2 are received, it is also possible to 
construct a system such that the radio telephone handset 5', (i.e., the 
transfer address telephone set) monitors the paging response signal 2 and 
the off-hook signal 2' from the radio telephone handset 5' and to send out 
a transfer impossible signal or a bell ringing signal to the radio 
telephone handset 5 requesting a transfer, when the paging response signal 
2 and the off-hook signal 2 are not sent back from the radio telephone 
handset 5' even when the predetermined interval has elapsed. 
Alternatively, it is also possible to construct a system such that the 
radio telephone handset 5 requesting transfer monitors a transfer 
termination signal sent back from the base station 4 and automatically 
generates an alarm tone when the transfer termination signal is not sent 
back from the base station even when the predetermined interval has 
elapsed, thus disenabling transfer, which urges the transfer operator to 
hook OFF so as to establish an office line connection. 
Although in the foregoing embodiments, a single pair of transmitter and 
receiver was used as the master apparatus, a plurality of pairs of the 
transmitters and receivers can also be used. 
Further, in the foregoing embodiments, this invention was applied to a 
telephone system of the multi-channel access sytem utilizing a single 
control channel and a plurality of speech channels. However, the invention 
is also applicable to a multi-channel system which utilizes only a 
plurality of speech channels and wherein a specific speech channel is made 
in the same manner as that utilizing the control channel.