JP2000269883A - Call area recognizing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a call area confirming method capable of reducing the cost of a device and reducing interference upon receiving a code by using one tone frequency selected among CTCSS frequencies as an identification code and transmitting a recognition signal at random and arbitrary timing which is set by an interval timer. SOLUTION: An interval timer is constituted as a random timer and prescribed time from one second to thirty second is automatically set at random, for example. A first radio station transmits a transmission frequency by loading a CTCSS allocated to oneself to a second radio station at timing A1 when a randomly set time T11 has elapsed. When the second radio station can receive the transmission frequency containing the CTCSS frequency, it is detected that the first radio station is within a call range. Since check is executed at random time, it is prevented that the checks of plural stations are overlapped and code reception interference occurs.

Description

DETAILED DESCRIPTION OF THE INVENTION

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication area confirmation method, and more particularly, to a communication area confirmation method for confirming whether or not a wireless communication device is located within a communication area in which communication can be performed with each other.

[0002]

2. Description of the Related Art There is known a system in which a plurality of wireless communication devices can simultaneously communicate using the same frequency. FIG. 6 shows an example of such a communication system.
In this case, each wireless station is assigned a different identification code. For example, in the system shown in FIG.
"010" is assigned as a digital code to the wireless station of (B), "001" is assigned to the wireless station of (B), and "010" is assigned to the wireless station of (C). In this case, even if the radio station A transmits to the radio station B at a certain frequency f and the radio station B receives the same frequency, the identification code given to each of the radio stations A and B is Because they are different, they cannot communicate with each other.

However, since the same identification code "010" is assigned to the radio stations A and C, if the two radio stations A and C are located within the communication area of each other, it is possible to make a call. Become. In this case, as a method for confirming that the wireless stations A and C are within the communication range of each other, the wireless stations A and C mutually detect an identification code given by a digital code,
When this is detected, the other station is informed that the terminal is in the call area, and when it is not detected, the other party is informed that the terminal is not in the call area. The confirmation of the call area can be performed by displaying on the display of the wireless station or by generating a predetermined signal sound.

FIG. 7 and FIG. 8 are control flowcharts showing such a conventional method of confirming a communication area. Now, the first wireless station and the second wireless station transmit and receive at the same frequency,
Assume that the same digital identification code is attached. Here, usually, the digital identification code is converted into a DTMF signal, added to a transmission frequency, and transmitted. When confirming the call area whether the first wireless station and the second wireless station can make a call, first, both wireless stations are provided. The call area check function is turned on (steps 101a and 101b). Next, a fixed timer for checking the communication area installed in the first wireless station is set to a predetermined time, for example, 60 seconds (step 102). When the set time set by the fixed timer expires, the own identification code is added to the predetermined transmission frequency f by the DTM.
The signal is converted into an F signal, added to the transmission frequency f, and transmitted to the second wireless station (step 103).

[0005] Since the second wireless station is in the standby state at this stage, it is determined whether or not the identification code at the transmission frequency f transmitted from the first wireless station matches its own identification code and can be received. Is detected (step 104). Here, if the reception can be detected, a mark (*) indicating the detection is displayed on the display, and the timer for checking the own communication area is set to 60 seconds (step 10).
5). On the other hand, if reception cannot be detected, (*) is not displayed and the timer is set to 60 seconds (step 106). After the fixed timer set time of 60 seconds has elapsed, the second wireless station adds its own identification code to the transmission frequency f and transmits it to the first wireless station (step 10).
7). The first wireless station determines whether or not this can be detected (step 108).

[0006] When the reception is detected, (（) is displayed as in the case of the second wireless station, and the timer is reset to 60 seconds again (step 109). If not detected, (*) is not displayed and the timer is reset to 60 seconds (step 110). When (こ の) is displayed on both wireless stations in steps 105 and 109 in this way, both wireless stations are in a call area and can make a call, so that a predetermined call is made. If a predetermined time has elapsed and it is attempted to check the call area again, the same operation as in step 103 is performed in step 111.

If reception is detected at step 112 in the second radio station, the display is continued as it is and the timer is reset to 60 seconds. However, if the detection is not possible, (☆) is turned off, a beep sound (notification sound) is output, and the second wireless station knows that the first wireless station is already located outside the communication area (step 114). ).
Thereafter, the timer is set again to 60 seconds (step 115).
The MF signal is added and transmitted to the first wireless station (step 116). Steps 117 to 120 of the reception detection procedure in the first wireless station are the same as steps 112 to 115 in the second wireless station. As described above, the conventional communication area checking method in the wireless device is executed at a predetermined fixed timing using the digital identification code converted into the DTMF signal and the fixed timer for confirmation.

[0008]

As described above, in the conventional call area checking method, the time (interval) from the end of the first check to the start of the next check is always set to a fixed time. Was. Therefore, when a plurality of wireless stations set (turn on) the call area check function at the same time, the intervals of all the wireless stations become constant, and the identification code cannot be correctly recognized due to interference at the time of receiving the identification code. In addition, there is a problem that it is recognized that it is out of the call area even though it is originally located in the call area.

In addition, since it is necessary to convert a digital identification code into a DTMF signal and add the DTMF signal to a transmission frequency before transmission, a circuit for converting the identification code into a DTMF signal is required and the apparatus becomes expensive. There was also the problem of becoming. SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and has as its object to provide a communication area confirmation method that reduces the cost of an apparatus and reduces interference upon code reception.

[0010]

According to the present invention, an acknowledgment signal including an identification code is transmitted / received between a first wireless station and a second wireless station at a predetermined timing, so that the first wireless station can communicate with the first wireless station. 2
A call area check method for checking whether or not a station is located within a call area.
The transmission of the confirmation signal is performed at an arbitrary random timing set by an interval timer using one tone frequency selected from the frequencies.

The first wireless station sets the interval timer when a switch for setting the call area confirmation function is turned on, and transmits the confirmation signal to the second wireless station after a set time has elapsed. When receiving the confirmation signal, the second wireless station sets the interval timer to an arbitrary set time, and returns the confirmation signal to the first wireless station after the set time has elapsed. At this time, the second wireless station may perform a confirmation display when receiving the confirmation signal.

The first wireless station may display a confirmation when receiving the reply of the confirmation signal. Further, when the first wireless station receives the reply of the confirmation signal,
The interval timer is reset, and after the lapse of the set time, the confirmation signal is retransmitted to the second wireless station. At this time, when the second wireless station receives the retransmission of the confirmation signal, the second radio station continues the confirmation display.

When the first radio station does not receive the reply of the confirmation signal, the first radio station changes the setting of the interval timer to a predetermined fixed time, and returns the confirmation signal to the second radio station. Is not performed. The second wireless station may cancel the confirmation display and / or output a notification sound when the confirmation signal is not retransmitted or when the confirmation signal is not retransmitted.

[0014]

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. First, in the present invention, a DTMF based on a conventional digital code is used as an identification code.
The CTCSS frequency was used instead of the signal.
The CTCSS frequency is also called the tone squelch frequency,
38 waves between 67 Hz and 250.3 Hz are allocated according to international standards. FIG. 4 shows the CTCSS numbers and their frequencies that can be selected in the CTCSS setting mode. This CTCSS frequency is used when carrying this tone on a transmission radio wave and communicating only with a certain partner, and is transmitted while being superimposed on the transmission frequency.

On the receiving side, the tone squelch frequency is cut off by a high-pass filter or a band-pass filter to extract an audio signal, so that the tone squelch frequency does not affect speech. FIG. 5 shows a schematic configuration of a communication system used in the communication area confirmation method of the present invention. Unlike the conventional communication system shown in FIG. 6, a tone (squelch) frequency specified by a CTCSS number is assigned to each of the radio stations A to C as an identification code. That is, the wireless station A is assigned the CTCSS number 1, the wireless station B is assigned the number 15,
The wireless station C is assigned the number 1 as an identification code. Therefore, the radio stations A and C can communicate at the same call frequency, but the radio stations A and B cannot communicate because the assigned CTCSS numbers are different. Since such a CTCSS frequency is used as an identification code, there is no need to convert a digital code into an analog code as in the related art, so that there is an advantage that a conversion circuit is not required and the apparatus is inexpensive.

In the confirmation method of the present invention, a call area check is performed.
Using a random timer as an interval timer for
I have. This allows multiple stations to check the calling area simultaneously.
And the intervals match,
Solving the problem of incorrect code detection
Can be. It should be noted that the communication area confirmation method of the present invention
In particular, CORDS (Communication
RangeDetectionSystem) function will be called.

FIG. 1 is a timing chart showing an example of a method for checking a call area according to the present invention. Here, a method of confirming the communication area between the first wireless station and the second wireless station is shown. At timing A ₀ , the CO of the first wireless station
The RDS function is turned on. On the other hand, it is assumed that the CORDS function is also turned on at a predetermined timing for the second wireless station. After turning on the CORDS function, the first wireless station automatically sets a built-in check interval timer and sets it to a predetermined time.

In the present invention, the interval timer is configured as a random timer.
A predetermined time from second to 30 seconds is automatically set at random. This random set time T ₁₁ the first radio station at a timing A ₁ has elapsed sends a transmission frequency f put a CTCSS signal assigned thereto to the second wireless station. When the second wireless station can receive the transmission frequency f including the CTCSS frequency, it is known that the first wireless station is within the communication range.

[0019]

[Table 1] Also set to a predetermined set time at random checking interval timer with a built-in self-similarly to the first radio station in the same time the timing B _1. Returns the transmission frequency f by placing a CTCSS signal to the first radio station at a stage when the set time T ₂₁ of the interval timer has elapsed (timing B _2).

The first radio station receives the CTC from the second radio station.
When can detect the transmission frequency f containing SS signal at timing A ₂ may display an antenna mark on its LCD display, sets the next check interval timer to a random set time T _12. Then, the transmitted on the CTCSS signal to a second radio station at a stage when the set time T ₁₂ elapses (timing A ₃₎ (Results 1).

However, when the confirmation signal from the second wireless station cannot be received, it is determined that the communication is out of the communication area, and the antenna mark is not displayed on the LCD display. Also, no confirmation signal is transmitted to the second wireless station (result 2). In addition,
In this case, the set time of the interval timer is not random but is changed to a predetermined fixed time, for example, 1 minute. This is because even if the other station is out of the communication area and the short-term confirmation signal is frequently sent by the random timer, the probability of detecting that the other station is in the communication area is low, and the battery consumption accompanying the transmission of the confirmation signal is low. To save money. The operation of the second wireless station depends on whether or not the first wireless station has received the acknowledgment signal. If the acknowledgment signal is sent from the first wireless station according to the result 1, the timing B
Antenna mark displayed as is continued interval timer in ₃ also given random set time T ₂₂ at random timer is set. However, when the confirmation signal is not sent based on the result 2, the reception is not detected, so that it is determined that the communication is out of the communication range, and the display of the antenna mark is turned off. In addition, a beep is generated to notify the user that the other station is out of the communication range.

The following procedure repeats the above procedure as long as the CORDS function is not turned off. FIGS. 2 and 3 show the timing chart described in FIG. 1 as a flowchart, and the flow itself is the same as the conventional flowchart shown in FIGS. 7 and 8. That is, Step 201 to Step 220 are performed in Step 10 respectively.
1 corresponds to step 120.

The difference from the conventional flow is that the interval timer for checking the communication area is a random timer and the identification code is a CTCSS signal. Further, the timer setting operation when the confirmation signal from the partner station is not detected is different. That is, in steps 206, 210, 215, and 220, the interval timer is changed from a random timer to a fixed timer. The set time of the fixed timer is longer than the maximum set time of the random timer. When the maximum set time of the random timer is 30 seconds, it is set to about one minute. That is, when the confirmation signal from the other party is not detected, the probability that the other party is within the communication area is low even if the confirmation signal is returned at random timing shorter than the time set by the fixed timer. This is to save battery consumption due to a simple check operation.

[0024]

As described above in detail based on the embodiment, the interval timer for checking the communication area is set as a random timer and the check is performed at a predetermined random time shorter than the fixed time. There is no chance that code checking interference will occur due to overlapping of station checks. In addition, the interval timer continues to be set as a random timer in the call zone, but switches to the fixed timer when located outside the call zone, so that battery consumption can be reduced. Further, since the CTCSS frequency is used as the identification code, it is not necessary to convert the identification code into an analog signal, and the manufacturing cost of the apparatus can be reduced.

[Brief description of the drawings]

FIG. 1 is a timing chart for explaining a confirmation method of the present invention.

FIG. 2 is a flowchart (part 1) showing a control flow of the confirmation method of the present invention.

FIG. 3 is a flowchart (part 2) showing a control flow of the confirmation method of the present invention.

FIG. 4 is a diagram showing values of a CTCSS frequency used in the present invention.

FIG. 5 is a diagram showing a schematic configuration of a communication system to which the confirmation method of the present invention is applied.

FIG. 6 is a diagram showing a schematic configuration of a communication system to which a conventional confirmation method is applied.

FIG. 7 is a flowchart showing a control flow of a conventional confirmation method (part 1).

FIG. 8 is a flowchart showing a control flow of a conventional confirmation method (part 2).

Claims (9)

[Claims] An acknowledgment signal including an identification code is transmitted and received between a first wireless station and a second wireless station at a predetermined timing, so that the first station and the second station are within a communication area. In a communication area confirmation method for confirming whether or not a caller is located, a method selected from a CTCSS frequency as the identification code
A communication area confirmation method, wherein the transmission of the confirmation signal is performed at a random arbitrary timing set by an interval timer using two tone frequencies. 2. The communication area check method according to claim 1, wherein the first wireless station sets the interval timer when a switch for setting a communication area check function is turned on, and after the set time has elapsed, the first wireless station sets the interval timer. Transmitting the confirmation signal to the second radio station. 3. The method according to claim 1, wherein the second wireless station sets the interval timer to an arbitrary set time when receiving the confirmation signal, and sets the first time after the set time has elapsed. And transmitting the confirmation signal to the wireless station. 4. The method according to claim 3, wherein the second wireless station performs a confirmation display upon receiving the confirmation signal. 5. The communication area confirmation method according to claim 3, wherein the first wireless station performs confirmation display when receiving a reply of the confirmation signal. 6. The communication area checking method according to claim 3, wherein the first wireless station resets the interval timer when receiving the reply of the confirmation signal, and resets the interval timer after the set time has elapsed.
Retransmitting the confirmation signal to the wireless station. 7. The method according to claim 6, wherein the second wireless station receives a retransmission of the confirmation signal,
A method for confirming a call area, wherein the confirmation display is continued. 8. The method according to claim 3, wherein the first wireless station sets the interval timer to a predetermined fixed time when the first wireless station does not receive the reply of the confirmation signal. A method of confirming a call area, wherein the method does not return the confirmation signal to the second wireless station. 9. The method according to claim 6, wherein the second wireless station does not receive a retransmission of the acknowledgment signal, or when the acknowledgment signal is not retransmitted. Canceling the confirmation display and / or outputting a notification sound. [0001]