KR100394829B1 - Method of receiving selective calling signal and its receiving device - Google Patents

Abstract

In a receiving device of a selective call signal type for receiving a transmission code having a series of signal codes including a preamble, a synchronization code, and a message code, the receiving device is capable of interfering with the interference and terminating the signal even when signal reception is interrupted. You can respond immediately. In the case of an interference state, the receiving device can immediately return to the signal receiving operation after the interference state is extinguished. The receiver of the selective call signal type of such a simple arrangement includes a synchronization signal generator which is reset when a preamble is detected while generating a signal having the same period as the synchronization code;

A reception circuit intermittently operated in response to a synchronization signal from the synchronization signal generator, a synchronization code detection circuit and a preamble detection circuit intermittently operated in response to the synchronization code, and a call code operating only when a synchronization code is detected It consists of a detection circuit.

Description

Receiving method of selective call signal and receiving device

The present invention relates to a method and an apparatus for receiving a selective call signal, and in particular, by receiving a transmission code system such as a selective call signal system in a transmitter of a mobile communication system in advance to receive a call signal in which a plurality of signals are continuously and repeatedly transmitted. The present invention relates to a receiving apparatus of a selective calling signal and a receiving method of the selective calling signal.

The selective call signaling system consists of a concatenation of a first code for informing transmission and a number of codes in a specified format. The series of codes designated as a format consists of a second code synchronized with a receiving device and a third code including an address code, message information, a check code, and the like.

2A shows the signal system. A typical signal system is called "POCSAG Signal System".

To reduce battery power consumption, receiver devices using this POCSAG signal system receive signals by intermittently operating. In addition, several designs for power saving have been proposed.

2 is a diagram showing a standby state for a first code and an operation after the first code is detected. 2 (a) and 2 (b) show the operation of the receiver device, which is a prior art Japanese Laid-Open Patent Application No. 63-13432 (see FIG. 3) and one embodiment thereof (see FIG. 5). The operation of these prior art is intended to facilitate the description of the present invention. FIG. 4 is a schematic block diagram showing an arrangement of a conventional receiver device operating as shown in FIG. 2 (b).

Next, FIG. 2 is described in detail. According to the method of FIG. 2 (a), the receiving circuit is turned on every time a predetermined time elapses to perform the detection operation of the preamble (first code). When the preamble is detected (i), the operation proceeds to the detection operation of the sync code SC (second code). Next, when the synchronization code SC (second code) is detected, synchronization is established. Based on this synchronization, the operation proceeds to the detection operation 4 of the subsequent synchronization code SC and the detection operation 3 of the call code (third code). By the way, as clearly explained in the above Japanese publication, when a series of signal groups is completely transmitted and another series of signal groups arrives, such a conventional system cannot capture these newly arrived signal groups. It has a flaw. In the termination by the signal interruption of FIG. 2 (a), when the sync code cannot be detected once or more, the operation proceeds intermittently to detect the preamble. (See the upper part of the lower right column of page 2 of Japanese Laid-Open Patent Publication No. 63-13432 and "x" in Figure 3 (a).)

According to the method of FIG. 2 (b), the detection operation of the synchronization code SC is omitted, and the synchronization state is determined using the periodicity of the call code.

Compared with the method of FIG. 2 (a), a better battery power saving effect can be obtained. In addition, a preamble detection operation is newly performed between two consecutive call codes in order to detect the arrival of a new preamble.

According to this operation, when the preamble is detected (i) and then the synchronization code SC is detected (O), the operation proceeds to the detection operation 3 of the calling code from this point in time. Next, the detection operation 3 'of the next call code is performed while using the call signal as the synchronization code.

FIG. 4 is a diagram showing the circuit arrangement of the receiver which operates as shown in FIG. 2 (b). The received data input from the antenna is demodulated by the receiving means 21, and the demodulated data is then sent to the decoder 22. In the decoder, first to third codes are determined and detected from the demodulated data according to the operation flow of FIG. 2 (b). These detection results are supplied to the timing controller, and then the switches S1 and S2 are turned on / off based on a predetermined timer value to perform the reception operation.

According to the conventional method (a) described above, the main purpose is to save battery power, and there is no special explanation for the measures after the series of signal groups are terminated. In the conventional method (b), the detection operation of the preamble is newly performed at the reception timing of the synchronization code, and a specific on-time is used for the reception device. To enhance battery power savings, this on time is chosen to be small enough to capture the preamble.

As mentioned above, the main purpose of the conventional system is to reduce the power consumption of the battery as much as possible. When the transmission operation for a series of signal groups is interrupted due to the occurrence of interference, signal reception is once stopped.

After waiting for the next transmitted preamble (first code) the information is read again. Alternatively, an operation for intermittently capturing the preamble is inserted. This acquisition time is kept to the minimum possible, thereby avoiding a reduction in battery saving efficiency.

The present invention provides a simple signal receiving method that can be quickly recovered to a signal receiving state while maintaining a function of suppressing battery power consumption even when the interference state is temporarily generated during the signal reception and the interference state disappears while being manufactured at low cost. The purpose is to provide a device.

It is another object of the present invention to provide a signal receiving method / apparatus capable of simultaneously detecting both a sync code and a preamble so that a data group can be immediately received even when a series of data groups arrives newly.

As used herein, the term "interference state" refers to a state of unreceivable caused by the following reason. That is, when a receiver enters a rear section of a large building along a tunnel or signal propagation direction, or when a high power transceiver transmits a signal in close proximity to such a signal receiver, an interference condition will occur.

In order to achieve the above objects, according to the present invention, the following receiving method and apparatus are used.

1) A method of receiving a selective call signal characterized by the following contents.

i) The receiving unit includes synchronizing signal generating means for intermittently outputting a synchronizing signal at a repetition period of the second code irrespective of each code detecting operation.

ii) Each time the synchronization signal of the synchronization signal generating means is received, the reception unit operates only for a predetermined time to enter into the detection operation of the first code and the second code.

iii) Upon detecting the first code, the synchronization signal generating means is reset to continue the operation of ii).

iv) Upon detecting the second code, the receiving unit enters into the detection operation of the third code by operating only for a predetermined time after the detection of the second code.

v) When the second code cannot be detected, the operation of the receiving unit returns to the operations of ii) to iv) after the operation of iv).

vi) When a predetermined third code is detected by the detecting operation of iv), the information is displayed.

2) The method of claim 1, wherein the first code is a preamble, the second code is a synchronization signal, and the third code is a call signal.

3) The method for receiving a selective call signal, characterized in that the transmission signal code system is a POCSAG signal system.

4) The predetermined time of operation ii) is a time interval of the second code, and the predetermined time of operation iv) is a time interval corresponding to the time position to which the third code is assigned. Receive method.

5) receiving means (2) for receiving the transmission signal; First code detecting means (3) to which an output of said receiving means (2) is input; Second code detecting means (4); Third code detecting means (5); Synchronization signal generating means (6) for continuously generating a repetitive signal having the same period as said second code of said transmission signal; First timing generating means (7) for generating a signal having a time width for detecting said second code in synchronization with the output of said synchronization signal generating means; Second timing generating means (8) for generating a signal having a time width for detecting the third code in synchronization with the output of the synchronization signal generating means when an output instruction signal is received from the second code detecting means (4); )and; Switch means (9) for turning on the operation of said receiving means (2) during the signal generation period of said first timing generating means (7) and said second timing generating means (8); And display means (11) for displaying the output of said third code detecting means (5),

The first code detecting means 3 outputs a reset signal to the synchronization signal generating means 6 when the first code is detected, and the second code detecting means 4 is the first timing generating means. When the second code is detected during the signal generation period of (7), and the second code is detected, an output instruction signal is sent to the second timing generating means (8), and the second code is not detected. And outputting an output stop signal, wherein said third code detecting means (5) performs the detecting operation of said third code in the output period of said second timing generating means (8).

6) The apparatus of claim 1, wherein the first code is a preamble, the second code is a synchronization signal, and the third code is a call signal.

7) The apparatus of claim 1, wherein the transmission signal code system is a POCSAG signal system.

8) The time width of the signal generated from the first timing generating means 7 is the time interval of the second code, and the time width of the signal generated from the second timing generating means 8 is applied to the third code. And a time interval corresponding to a time position from the second code allocated in advance.

As described above, the reception apparatus of the present invention includes a synchronization signal generator for generating the synchronization signal at a repetition period of a second code. The first code detecting means and the second code detecting means are operated by using such a synchronization signal. Each time the first code is detected by the first code detecting means, the synchronization signal generator is reset. As a result, since the synchronous state of the receiver of simple construction can be maintained even when signal transmission is interrupted, such a receiver can respond to any interruption and completion of signal transmission. That is, even if a disturbance occurs temporarily, the receiving device can immediately recover signal reception after the disturbance disappears. In addition, since the intermittent operation is maintained, sufficient battery power saving can be achieved as compared with the conventional receiver.

Hereinafter, to help understanding of the present invention, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of a signal receiving apparatus operating in a POCSAG signal system to which the present invention is applied. 2 is a diagram illustrating the conventional receiving operation (a, b) and the receiving operation (c) of the present invention, and FIG. 3 is the conventional receiving operation (a, b) and the present invention when a disturbance condition occurs. Is a diagram illustrating the reception operation (c) of the circuit.

As described above, the POCSAG signal consists of a preamble (first code) located in the head portion and one or more batches following the preamble (see also FIG. 2A). The group is arranged in sync code SC (second code) and call code (third code). In this example, one group consists of 544 bits (equivalent to the period of the sync code). The sync code SC is arranged in 32 bits, and the calling code following this sync code SC is similarly configured in 32 bits. The call code is allocated 224 to 287 bits from the end of the sync code.

Also in FIG. 1, reference numeral 1 denotes an antenna for receiving a POCSAG signal, and reference numeral 2 shows a receiving circuit (corresponding to a receiving means). The signal received by the receiving circuit 2 is a preamble detecting circuit (corresponding to the first code detecting means), a synchronous (synchronizing) code detecting circuit 4 (corresponding to the second code detecting means), and a call code detecting circuit ( 5) (corresponding to the third code detecting means).

Reference numeral 3 is a preamble detection circuit that detects the preamble from the received signal and generates a reset signal to the counting circuit (corresponding to the synchronous signal generating means) when the preamble is detected.

Reference numeral 4 is a diagram showing a sync code detection circuit for detecting whether a sync code SC is present in the received signal. When the sync code SC is detected, the sync code detection circuit 4 The output instruction signal is supplied to the second timing generating circuit (means) 8. When no sync code SC is detected, the sync code detection circuit 4 supplies an output stop signal to the second timing generation circuit 8.

Reference numeral 5 shows a call code detection circuit for detecting a preferred call code (third code) from the received signal at the time of receiving the output from the second timing generation circuit 8.

Reference numeral 6 denotes a counting circuit (corresponding to a synchronous signal generating means) for supplying a count value (synchronizing signal) to the first timing generating circuit (means) 7 and the second timing generating circuit (means) 8. . The count value is set at the same period as in the sync code, in which case it is selected to be 544 bits. The counting circuit 6 outputs a count value each time the clocks 0 to 543 bits are counted. The counting circuit 6 is reset in response to a reset signal generated when the first code detecting circuit 3 detects the preamble.

Reference numeral 7 shows a first timing generating circuit. The first timing generation circuit for generating a time signal corresponding to the elapsed time of the synchronization code is displayed while the rule for setting the operation time period with the second code detection circuit is implemented. In this case, since the length of the synchronization code is 32 bits, the first timing generation circuit 7 generates a time signal for counting 0 to 31 bits (32 bits) upon reception of the output from the counting circuit 6. This output constitutes an ON signal of the switch circuit 9 and is also sent to the second code detection circuit 4.

Reference numeral 8 denotes a second timing generating circuit (means) for implementing a rule for defining the operation period of the call code detection circuit 5. The output period is a period defined by the sync code after it is detected, and the position of the assigned call code is detected.

In this case, the output period corresponds to the period defined by the 224 th bit to the 287 th bit (62 bit period) after the synchronization code is detected. Upon reception of the output instruction signal from the synchronous code detection circuit 4, this output becomes the ON signal of the switch circuit 9 and is also sent to the call code detection circuit 5. No output signal is generated upon reception of the output stop signal. As a result, not only the on signal is supplied to the switch signal 9, but also the reception circuit 2 and the call code detection circuit 5 are not operated.

Reference numeral 9 denotes a switch circuit for turning on the operating power supply 10 of the receiving circuit 2 only during the output periods of the first timing generating circuit 7 and the second timing generating circuit 8.

Reference numeral 11 denotes an alarm generation circuit (display means) for displaying information detected by the call code detection circuit 5, and may be constituted by a speaker, a buzzer, and a liquid crystal display device.

Now, on the basis of the operation chart shown in FIG. 2, the operation of the receiver according to the embodiment of the present invention will be described in comparison with the prior art.

2 (a) is a Japanese patent application No. The prior art described in 63-13432 is shown, and FIG. 2 (b) shows Japanese Laid-Open Patent Application No. Corresponding to one embodiment described in 63-13432, Figure 2 (c) illustrates the present invention.

In this operation chart, the indication "x" indicates the time or preamble at which no synchronous code is detected. The indication " o " indicates the time after synchronization is formed. The display " o " indicates the time when the preamble is detected. Indication (1) indicates a period in which the receiving circuit is intermittently operated to detect the preamble. The display (2) shows a period during which the synchronization code is detected after the preamble is detected in the state where the power supply of the receiving circuit is turned on. This period is set slightly longer than the length of the preamble and the length of the sync code. Display (3) indicates a period during which the calling code is detected after the synchronization code is detected. The indication 3 'indicates the period during which the next call code is detected after one call code is detected. Indication (4) indicates a period during which the next sync code is detected after one sync code is detected. In addition, the display 4 'further indicates a period during which the preamble detection operation is performed.

As shown in (1), in the state in which no POCSAG signal is transmitted, the prior art second (a), second (b) and second invention (t) have the same meaning. That is, the reception circuit is turned on intermittently every time a certain period has elapsed, and the preamble standby operation is performed. Incidentally, in FIG. 2 (b), as described above, the detection operation of the synchronization code SC is omitted, and the synchronization state is determined by using the periodicity of the calling code. The preamble is detected by additionally providing a preamble detection operation between two consecutive call codes. As a result, the receiving device also performs a synchronous state detection operation while the preamble is retrieved.

As described above, the counting circuit 6 is a circuit set to output a synchronizing (synchronizing) signal having the same period (i.e., 544 bit period) as in the synchronizing code. Each time the synchronization signal is received, a first timing generation circuit 7 is activated, and an output signal of the first timing generation circuit 7 (a pulse signal having the same length as in the synchronization code, 0 to 31 bit period). Is supplied to the switch circuit 9, whereby the receiving circuit 2 is operable for a period of 0 to 31 bits. The output signal derived from the receiving circuit 2 is supplied to the first code detecting circuit 3 waiting for the arrival of the preamble. In addition, the output signal from the first timing generation circuit 7 is input to the second code detection circuit. The second code detection circuit is operated at the same timing as in the first code detection circuit 3, and at the same time, the synchronization code detection operation is performed.

When the first code detection circuit 3 finds the preamble, it sends a reset signal to the counting circuit 6 to reset the counting circuit 6. Next, in response to the output derived from the setting coefficient circuit 6, the first timing generation circuit 7 is operated to generate a timing signal. In response to this timing signal, the switch circuit 9, the preamble detection circuit 3 and the sync code detection circuit 4 are operated. Next, this operation is repeatedly performed until the sync code detection circuit 4 detects the sync code (indicated by?).

When the sync code detection circuit 4 detects the sync code (indicated by o), the output instruction signal is sent to the second timing generation circuit 8. As described above, the second timing generation circuit 8 generates a signal having the above period (cycles from 224 to 287 bits) in synchronization with the coefficient output value of the counting circuit. From the time when the detection operation of the sync code ends, until the call code is found, the period is defined thereby. Upon reception of the output instruction signal generated from the synchronous code detection circuit 4, the second timing generation circuit 8 generates a timing signal. Since this output timing signal is input to the switch circuit 9 and the call code detection circuit 5, the reception circuit 2 and the call code detection circuit 5 are brought into an operating state. Therefore, upon reception of the transmission signal, the reception circuit 2 supplies the reception signal to the call code detection circuit 5. When the call code detection circuit 5 finds the call code within this period, an alarm signal is generated to operate the alarm signal generation circuit 11. Note that no timing signal is generated from the second timing generation circuit 8 during the period (from 0 to 223 bits) from the synchronization code detection to the allocation period and after the termination of the calling code.

Thereafter, because the period (554 bits) of the next synchronization code arrives, the counting circuit 6 outputs a synchronization signal. The first timing generation circuit 7 outputs a timing signal during a period corresponding to the timing period of the synchronization code. Next, while detecting the sync code, the above operation is repeated.

On the other hand, in Fig. 2 (a), each time a sync code is detected, the detection operation of the call code 3 and the subsequent sync code 4 is continued based on this detection timing. In FIG. 2 (b), a sync code is detected. In addition, when the sync code is detected (3), if the detection operation of the sync code is canceled, the detection operation 3 'of only the calling code is continued. Since this synchronous code detection operation is stopped, battery power saving operation can be achieved. Note that the preamble detection operation is inserted between the two calling codes.

Referring now to FIG. 3, comparing the prior arts (a), (b) and the present invention (c), the operation when the interruption occurs during signal reception and the signal reception is temporarily stopped will be described.

Normally, even when a series of signals are transmitted to the POCSAG signal system, the code used to indicate the end of the signal transmission is not sent. Therefore, as shown in FIG. 3 (a), since the preamble x is not detected during the detection of one of the synchronization code or the calling code, when the signal transmission is interrupted, interference or a series of signal transmissions are detected. There is no means for determining whether the signal transmission is interrupted by the termination of. Therefore, if the synchronization state is maintained for a long time, there is a drawback that the series of newly transmitted signals cannot be received when the series of preceding transmission signals is terminated. Thus, the operating state proceeds asynchronously, and the detection operation of the preamble is newly started immediately after this transition. In FIG. 3 (b), since the period for detecting the preamble is limited to the minimum value in order to solve such a defect, the detector is intermittently operated at the same timing as in the sync code.

According to the present invention, when the second code detection circuit 4 cannot detect the synchronization code during signal reception, an output stop signal is sent to the second timing generation circuit 8 so as not to output the second timing signal. As a result, the reception circuit 2 and the call code detection circuit 5 become inoperative. However, there is no adverse effect on the counting operation of the counting circuit 6, and the operation continues while the synchronous state is maintained. Therefore, since the first timing generating circuit 7 is continuously operated by receiving the counting output signal from the counting circuit 6, the receiving circuit 2, the preamble detecting circuit 3 and the sync code detecting circuit 4 also operate. do. Thus, while maintaining synchronization with the received transmission signal, the receiving device of the present invention can respond immediately to the arrival of a new preamble and can quickly recover from subsequent interference.

In Fig. 3A, when the sync code cannot be detected (x), the sync code detection operation is performed again. Even if the sync code cannot be detected again (following x), the transmission of the series of signals is considered to be stopped. Therefore, the detection operation of the preamble is newly entered. In FIG. 3 (b), if the call code recovers from the disturbing state when it cannot be detected (x), the receiving device can be brought back into the signal receiving state. Since the preamble detection operation is embedded in the consecutive call code, it can be started immediately when the signal transmission is terminated.

Note that since the battery power saving operation is enhanced in FIG. 3 (b), this detection operation is stopped after the synchronization signal is detected, and the tie of the call code is used as the synchronization signal. As a result, even when entering the preamble detection operation, the receiving apparatus maintains the synchronous state in addition to the preamble detection operation and uses the call code as the timing. Therefore, when the preamble is found, similarly to the third (a), the battery power saving operation cannot be effectively performed.

In contrast, according to the present invention, as a reference time signal supplied to the first timing generation circuit 7 and the second timing generation circuit 8, a counting circuit reset by the preamble detection circuit 3 (synchronization signal generation) Since the counting output signal from the means (6) is commonly used, the receiver and the circuit arrangement can be made simple and at low cost. In addition, the receiver may respond to the synchronization state after recovering from the interference, and may also respond to the synchronization state of the newly transmitted signal. When the preamble is found, the battery power saving operation can be performed similarly to the third (a).

In recent years, as the amount of information to be transmitted has increased significantly, many batches following the preamble will be used. Therefore, the transmission time for transmitting a series of signals is extended, and the frequency tends to increase when the signal transmission is interrupted due to interference. In addition, there is a considerable demand to reduce the manufacturing cost of the receiver. As described above, according to the present invention, the reception method as well as the reception device capable of immediately responding to the termination of the signal transmission and the temporary interference while maintaining the power saving function can be realized at low cost.

According to the present invention, the second code detection operation is performed simultaneously with the first code detection operation. The synchronization signal output from the synchronization signal generating means, which is set in advance each time the first code is detected, is commonly used as a reference time signal for the second code detection operation and the third code detection operation. Therefore, the arrangement of the receiving device can be made simply and at low cost while maintaining the battery power saving function. Even when the signal reception is temporarily interrupted, since the reception of the signal can be continued immediately since the communication state is restored because it does not adversely affect the normal signal reception operation, such a receiver can effectively respond to the occurrence of interference. In addition, even when signal transmission is interrupted by the termination of a series of signal transmissions, if a new group of signal groups arrives, such a receiver can immediately and effectively respond to the new signal arrival.

1 is a view schematically showing a circuit arrangement of a receiver according to an embodiment of the present invention;

2 is an explanatory diagram for explaining a signal receiving operation of the receiving device shown in FIG.

3 is an explanatory diagram for explaining the signal reception operation of the reception device shown in FIG. 1 when compared to the prior art when a disturbance condition occurs;

4 is a diagram schematically showing a circuit arrangement of a conventional receiver.

* Explanation of symbols for the main parts of the drawings

2: receiving circuit 3: preamble detecting circuit

4: Sync code detection circuit 5: Call code detection circuit

6: counting circuit 7: first timing generating circuit

8: second timing generating circuit 9: switch circuit

10: power supply 11: alarm generation circuit

21 receiving means 22 decoder

23: timing controller 24: switch

25: switch

Claims (8)

Periodically, a code system has been created that connects a number of preformatted code sequences with the first code at the head point, The code string, in which the format is specified in advance, intermittently receives, by the receiving unit, a transmission signal consisting of a second code and a third code constituting a synchronization code, and selectively selects a predetermined third code from the transmission signal. In the method for receiving a selective call signal received by, i) the receiving unit includes synchronizing signal generating means for intermittently outputting a synchronizing signal at a repetition period of the second code irrespective of each code detecting operation, ii) every time the synchronization signal of the synchronization signal generating means is received, the reception unit operates only for a predetermined time to enter into the detection operation of the first code and the second code, iii) upon detecting the first code, the synchronization signal generating means is reset to continue operation of the ii), iv) upon detecting the second code, the receiving unit enters into the detection operation of the third code by operating for only a predetermined time after the detection of the second code, v) when the second code cannot be detected, the operation of the receiving unit returns to the operations of ii) to iv) after the operation of iv), vi) When the predetermined third code is detected by the detecting operation of iv), the information is displayed. The method of claim 1, Wherein the first code is a preamble, the second code is a synchronization signal, and the third code is a call signal. The method according to claim 1 or 2, And the transmission signal code system is a POCSAG signal system. The method according to claim 1 or 2, The predetermined time of operation ii) is a time interval of the second code, and the predetermined time of operation iv) is a time interval corresponding to a time position to which the third code is assigned. . Periodically, a code system has been created that connects a number of preformatted code sequences with the first code at the head point, The code string, in which the format is specified in advance, intermittently receives, by the receiving unit, a transmission signal consisting of a second code and a third code constituting a synchronization code, and selectively selects a predetermined third code from the transmission signal. In the method for receiving a selective call signal received by, Receiving means (2) for receiving said transmission signal; First code detecting means (3) to which an output of said receiving means (2) is input; Second code detecting means (4); Third code detecting means (5); Synchronization signal generating means (6) for continuously generating a repetitive signal having the same period as said second code of said transmission signal; First timing generating means (7) for generating a signal having a time width for detecting said second code in synchronization with the output of said synchronization signal generating means; Second timing generating means (8) for generating a signal having a time width for detecting the third code in synchronization with the output of the synchronization signal generating means when an output instruction signal is received from the second code detecting means (4); )and; Switch means (9) for turning on the operation of said receiving means (2) during the signal generation period of said first timing generating means (7) and said second timing generating means (8); And display means (11) for displaying the output of said third code detecting means (5), The first code detecting means (3) outputs a reset signal to the synchronization signal generating means (6) when detecting the first code, and the second code detecting means (4) generates the first timing generating means ( When the second code is detected during the signal generation period of 7) and the second code is detected, an output instruction signal is sent to the second timing generating means 8, and when the second code is not detected. And outputting an output stop signal, wherein said third code detecting means (5) performs the detecting operation of said third code in the output period of said second timing generating means (8). The method of claim 5, And the first code is a preamble, the second code is a synchronization signal, and the third code is a call signal. The method according to claim 5 or 6, And said transmission signal code system is a POCSAG signal system. The method according to claim 5 or 6, The time width of the signal generated from the first timing generating means 7 is the time interval of the second code, and the time width of the signal generated from the second timing generating means 8 is previously assigned to the third code. And a time interval corresponding to a time position from said second code.