JP2021150894A - Communication device and control method therefor - Google Patents

Abstract

To provide a communication device and a control method therefor, which can immediately recognize the reception of an APRS message if a user is located at a place apart from the communication device.SOLUTION: A communication device 100 includes: receiver units 2-4; a control unit 1 which determines whether a forwarding function is valid or invalid; and automatic forwarding means 2-4. When the receiver units 2-4 receive an APRS message M1 transmitted from another communication device 100, and when the control unit 1 determines that the forwarding function is valid, the automatic forwarding means 2-4 transfers transfer information M4, which at least includes the APRS message M1, to an Internet mail address which is set as a transfer destination, through an APRS gateway station 20 and an APRS server 30 connected to the APRS gateway station.SELECTED DRAWING: Figure 1

Description

The present invention relates to a communication device and a control method of the communication device, and more particularly to a communication device for transmitting and receiving packet data and a control method of the communication device.

The APRS (Automatic Packet Reporting System) message function is used when you want to send a message by specifying a specific partner station. APRS messages are sent and received as single packet data different from beacons. The partner station receives the APRS message and sends back a receipt confirmation message (ACK) to its own station. The APRS message is sent up to 5 times until the receipt confirmation message (ACK) is received.

In addition, when the own station receives an APRS message and cannot directly receive the user's operation input, there is a message automatic response function that replies a preset response message to the partner station. This response message is prefixed with "AA:" which means "Auto Answer message". In addition, Patent Document 1 discloses a communication device related to such an automatic message response function.

Japanese Unexamined Patent Publication No. 2012-033184

The APRS message sender who sent the APRS message can know the reception of the APRS message and the absence of the APRS message recipient by the automatic message response function. However, the APRS message recipient cannot immediately recognize the reception of the APRS message when he / she is away from the communication device.

Therefore, an object of the present invention is to provide a communication device capable of immediately recognizing the reception of an APRS message even when the user is away from the communication device, and a method for controlling the communication device.

The communication device according to this embodiment is
Receiver and
A control unit that determines whether the transfer function is enabled or disabled, and
Equipped with automatic forwarding means,
When the receiving unit receives the APRS message transmitted by another communication device and the control unit determines that the transfer function is valid, the automatic transfer means transfers the transfer information including at least the APRS message to APRS. Forwards are made to the Internet mail address set as the forwarding destination via the gateway station and the APRS server connected to the APRS gateway station.

The control method of the communication device according to this embodiment is
Steps to receive APRS messages sent by other communication devices,
Steps to determine whether the automatic forwarding function is enabled or disabled,
When the APRS message is received and the automatic transfer function is determined to be valid, at least the transfer information including the APRS message is transferred via the APRS gateway station and the APRS server connected to the APRS gateway station. It includes a step of forwarding to the Internet mail address set as the destination.

According to the present embodiment, even if the user is away from the communication device, the reception of the APRS message can be immediately recognized.

It is a block diagram which shows the structure of the communication apparatus which concerns on Embodiment 1. FIG. It is the schematic which shows one operation example of the example of the communication device which concerns on Embodiment 1. FIG. It is a figure which shows an example of the setting screen. It is a flowchart which shows the message reception processing. It is a flowchart which shows the message reception processing. It is a flowchart which shows the message creation process for E-mail. It is a table which shows the relationship between each step in the message composition process for E-mail and the message for E-mail. It is a figure explaining each character string which constitutes a message for E-mail. It is a flowchart which shows the response message command creation process. It is a flowchart which shows the process which performs the QSY function using VoIP. It is a figure which shows one display example of a display.

Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings. However, the present invention is not limited to the following embodiments. Further, in order to clarify the explanation, the following description and drawings have been simplified as appropriate.

(Embodiment 1)
The first embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of a communication device according to the first embodiment.

As shown in FIG. 1, the communication device 100 includes a control unit 1, a DSP 2, a transmission / reception circuit 3, and an antenna 4.

The control unit 1 controls each configuration of the communication device 100. The control unit 1 has, as a hardware configuration, for example, an arithmetic circuit having a CPU (Central Processing Unit), a storage device having a program memory, a data memory, other RAM (Random Access Memory), a ROM (Read Only Memory), and the like. May be provided. The control unit 1 acquires data from each configuration of the communication device 100, and calculates various data by an arithmetic circuit according to a program stored in the storage device. The control unit 1 determines whether the transfer function and the automatic response function are enabled or disabled.

The DSP (Digital Signal Processor) 2 is a processor that performs digital signal processing. A control unit 1, a transmission / reception circuit 3, a microphone 5, and a speaker 6 are connected to the DSP 2. An antenna 4 is connected to the transmission / reception circuit 3.

The transmission / reception circuit 3 receives data transmitted by another communication device (not shown) via the antenna 4. The other communication device may have the same configuration as the communication device 100, or may have a different configuration. The DSP 2 acquires the data received by the transmission / reception circuit 3. The format of the acquired data may be a packet. It may indicate the acquired data, characters, position, weather, and the like. The DSP 2 demodulates the acquired data, decodes the character string of the packet included in the data, and supplies the data to the control unit 1. The DSP 2, the transmission / reception circuit 3, and the antenna 4 function as a receiving unit. The control unit 1 analyzes the supplied packet.

The control unit 1 assembles packet data. The DSP2 modulates the assembled packet data to generate a signal. The transmission / reception circuit 3 amplifies the signal generated by the DSP 2 and transmits it via the antenna 4. The DSP 2, the transmission / reception circuit 3, and the antenna 4 function as automatic transfer means.

The communication device 100 may further include a microphone 5, a speaker 6, a GNSS module 7, a non-volatile memory 8, a LAN port 9, a display 10, a PTT switch 11, an operation unit 12, and an RTC 13.

The microphone 5 collects the voice emitted by the user of the communication device 100 and converts it into a voice signal. DSP2 performs processing such as band limitation on this audio signal to generate a modulated wave. The transmission / reception circuit 3 modulates the carrier wave with the modulated wave generated by the DSP 2, and transmits the carrier wave via the antenna 4.

When the DSP2 acquires voice data, it D / A-converts the acquired voice data, demodulates and combines the acquired voice data to generate a voice signal. The speaker 6 emits sound based on the audio signal generated by the DSP 2.

The GNSS module 7 includes an antenna for receiving radio waves from satellites for the Global Navigation Satellite System (GNSS) and a receiving unit for receiving GNSS signals output by the antenna. GNSS is GPS (Global Positioning System) as an example. The GNSS module 7 acquires position information indicating the position of the communication device 100 and supplies it to the control unit 1. When the communication device 100 is not movable together with the user and is fixed at a predetermined position, the position information of the communication device 100 may be stored in the non-volatile memory 8.

The non-volatile memory 8 is, for example, an EEPROM (Electrically Erasable Programmable Read Only Memory). The non-volatile memory 8 may record, for example, an APRS message, a forwarding address of an APRS message, or the like. The display 10 may include touch keys while displaying predetermined information.

The PTT (Push To Talk) switch 11 is pressed by the user in order to perform an operation in which the user speaks and transmits an audio signal. The control unit 1 keeps 100 in the reception standby state when the PTT switch 11 is not pressed, and keeps the communication device 100 in the transmission state when the PTT switch 11 is pressed. The operation unit 12 receives an operation input from the user. The content of the received operation input is, for example, to enable or disable at least one of the transfer function and the automatic response function. The RTC (Real Time Clock) 13 generates time information by measuring the time. This generated time information may be used as a time stamp.

(One operation example)
Next, an operation example of the communication device 100 will be described with reference to FIG. FIG. 2 is a schematic view showing an operation example of an example of the communication device shown in FIG. This operation example shows a message forwarding function (Forward function) for forwarding an APRS message to an E-mail terminal owned and operated by the user of the communication device 100.

The terminal 100a and the terminal 100b shown in FIG. 2 are examples of the communication device 100 shown in FIG. The call sign "AAAAAA-7" is assigned to the terminal 100a, and the call sign "BBBBBB-7" is assigned to the terminal 100b. Strictly speaking, the call sign is assigned to the radio station including the communication device, but in this case, it is treated as consent and explained. In this one operation example, the terminal 100b is preset to enable (ON) the message forwarding function.

The terminal 100a receives the operation input by the user of the terminal 100a and transmits the transmission APRS message M1 to the terminal 100b. When the terminal 100b receives the transmission APRS message M1 from the terminal 100a, the terminal 100b transmits a reception confirmation APRS message M2 (ACK) to the terminal 100a.

The terminal 100b transmits the transfer APRS message M4 (transfer information). The forwarded APRS message M4 includes a transmitted APRS message M1.

Further, the transferred APRS message M4 may be the transferred information including the Internet line connection destination information of the terminal 100b. The Internet line connection destination information is information related to remote control on the terminal 100b side. The control unit of the terminal 100b may accept the remote control of the terminal 100b from the E-mail terminal 40 set based on the Internet line connection destination information of the terminal 100b. For example, an Internet mail address that can be received by the terminal 100b, an IP address of the terminal 100b, and the like. As an example of remote control of the terminal 100b from the E-mail terminal 40, as will be described later, there is a process of executing a QSY function for setting the communication frequency of the terminal 100b using VoIP (see FIG. 7).
Further, when the terminal 100b receives the response message to the transmitted APRS message M1 included in the transferred APRS message M4 via the Internet line connection unit by remote operation from the E-mail terminal 40, the terminal 100b transmits the transmitted APRS message M1. Allows the reply message to be sent as a reply APRS message to other communication devices.

The call sign "CCCCCC-1" is assigned to the I-GATE 20. When the I-GATE 20 receives the forwarded APRS message M4, the I-GATE 20 forwards the forwarded APRS message M4 to the APRS server 30. Here, I-GATE 20 is used, but an APRS gateway station other than I-GATE may be used.

Further, the APRS server 30 forwards the forwarded APRS message M4 to a predetermined Internet mail address (E-mail destination). The E-mail terminal 40 only needs to be able to receive the mail forwarded to this Internet mail address. The E-mail terminal 40 is a personal computer, but may be, for example, a tablet, a smartphone, or the like.

The E-mail terminal 40 notifies the user of the terminal 100b of the forwarded APRS message M4. In many cases, the user of the E-mail terminal 40 and the user of the terminal 100b are the same person. Further, in many cases, the E-mail terminal 40 is located or carried in a place where the user of the terminal 100b can operate it. Since the transferred APRS message M4, that is, the transferred information includes the content of the transmitted APRS message M1, the user of the terminal 100b can confirm the content of the transmitted APRS message M1 from the transferred APRS message M4.

An application capable of remotely controlling the terminal 100b is installed in the E-mail terminal 40, and a response message can be transmitted to the terminal 100b via the Internet 50 and the modem 60 by using, for example, a command. The E-mail terminal 40 accepts an operation input from the user of the terminal 100b, for example, an input for clicking an E-mail link. Then, in the E-mail terminal 40, the call sign of the partner station and the message line number are automatically set, and the PC application is started in the state where the response message is input.

When the automatic response message function is enabled, the terminal 100b can replace the automatic response message M3 with a command message until the automatic response waiting time elapses. The terminal 100b transmits the automatic response message M3 to the terminal 100a.

From the above, when the terminal 100b receives the transmission APRS message M1, the transmission APRS message M1 can be forwarded to the forwarding mail address. Therefore, the user of the terminal 100b can immediately check the content of the forwarded APRS message forwarded to the forwarding e-mail address by using the E-mail terminal 40. As a result, even if the user of the terminal 100b is away from the terminal 100b and cannot confirm the reception of the transmitted APRS message from the terminal 100b, the content of the transmitted APRS message M1 can be immediately confirmed.

When the message forwarding function is set to disabled (OFF), the terminal 100b does not carry out the above-mentioned one operation example.

(Message forwarding function setting screen)
Next, a setting screen for setting the message forwarding function will be described with reference to FIG. FIG. 3 is a diagram showing an example of a setting screen.

As shown in FIG. 3, the setting screen 110 displays "APRS Message Forward", "OFF", "ON (E-mail1)", "ON (E-mail2)", "ON (E-mail3)", etc. indicate. The setting screen 110 is a specific example of the display 10 shown in FIG. 1, or is a specific example of the display 10 of any of the terminals 100a and 100b shown in FIG. The setting screen 110 is used for setting the message forwarding function. The setting screen 110 accepts an input from the user to select any one of "OFF", "ON (E-mail1)", "ON (E-mail2)", and "ON (E-mail3)". The setting screen 110 accepts an input "ON (E-mail1)" from the user. It is preferable that there are a plurality of e-mail addresses that can be set because they can be switched according to the situation. The number of e-mail addresses that can be set is three, but it is preferable that the number is one or more.

(Message reception processing)
Next, an example of the message reception process of the terminal 100b will be described with reference to FIGS. 4A and 4B. 4A and 4B are flowcharts showing message reception processing.

Receive the packet (step ST11). Subsequently, the DTI (Data Type Identifier) of the received received packet is determined (step ST12).

When the DTI is ":" (step ST12: YES), since the received packet is a message packet, the destination call sign is determined (step ST13). If the DTI is other than ":" (step ST12: NO), the received packet is not a message packet, so the message receiving process is terminated.

Subsequently, it is determined whether or not the destination call sign and the own station call sign match by comparing the character strings (step ST13). The own station call sign is set in the communication device 100.

When it is determined that the destination call sign and the own station call sign match (step ST13: YES), it is determined that the received packet is an APRS message (step ST14). If the destination call sign and the own station call sign do not match (step ST13: NO), the message reception process ends because the received packet is not a message addressed to the own station.

Subsequently, the call sign of the partner station is acquired (step ST15). Specifically, the call sign portion of the partner station is taken out from the received packet and stored.

Subsequently, the message body is taken out from the received packet and stored (step ST16). Subsequently, the line number is taken out from the received packet and stored (step ST17). Subsequently, a packet of the reception confirmation APRS message M2 (ACK) is created and transmitted (step ST18).

Subsequently, it is determined whether or not the message forwarding function (Forward function) is enabled (ON) or disabled (OFF) (step ST19). When the message forwarding function is enabled (step ST19: YES), a message for E-mail is created (step ST20). Details of this step ST20 will be described later using the flowcharts shown in FIGS. 5A to 5C. When the message forwarding function is disabled (step ST19: NO), the process proceeds to the determination of automatic message response (step ST22).

Then, the created E-mail message is transmitted (step ST21).

Subsequently, it is determined whether or not the automatic message response function is enabled (ON) or disabled (OFF) (step ST22). When the automatic message response function is enabled (step ST22: YES), the progress of the automatic response waiting time is monitored (step ST23: NO). When the automatic response waiting time has elapsed (ST23: YES), the process proceeds to the automatic response message response processing (steps ST24 to ST26). The automatic response waiting time is set to a predetermined time. If the automatic message response function is disabled (step ST22: NO), the message reception process ends.

Subsequently, it is determined whether or not the command for the response message has been received (step ST24). When the command for the response message is not received (step ST24: NO), the preset message is replied as the automatic response message M3 (step ST25).

When the command for the response message is received (step ST24: YES), the command message is replied as the automatic response message M3 by replacing it with the preset message (step ST26).

(Message creation process for E-mail)
Next, the E-mail message creation process will be described with reference to FIGS. 5A to 5C. FIG. 5A is a flowchart showing an E-mail message creation process. FIG. 5B is a table showing the relationship between each step in the E-mail message creation process and the E-mail message. FIG. 5C is a diagram illustrating each character string constituting the message for E-mail.

This E-mail message creation process is the details of step ST20 shown in FIG. 4B, and is a process of assembling an E-mail message.

Set one character of ":" (colon) to start setting the destination call sign area (step ST31). Subsequently, the character string "EMAIL" is set in the destination call sign area (step ST32). Since the destination call sign area is fixed to 9 characters, set 4 "" (spaces) after "EMAIL". To start setting the message body area, set one character of ":" (colon) (step ST33).

At the beginning of the message body area, the e-mail address of the destination is set (step ST34). The destination E-mail address is set by the APRS message forwarding function, and is "abc@def.com" in the examples shown in FIGS. 5B and 5C. Then, one character of "" (space) is set (step ST35).

Then, the e-mail address of the reply destination is set (step ST36). The reply destination E-mail address is the Internet mail address of the terminal 100b, which is "def@def.com" in the examples shown in FIGS. 5B and 5C. Subsequently, as in step ST35, one character of "" (space) is set (step ST37).

Subsequently, the IP address of the terminal 100b is set (step ST38). This IP address is "111.222.33.44" in the example shown in FIGS. 5B and 5C. Subsequently, as in step ST35, one character of "" (space) is set (step ST39).

Subsequently, the QSY information is set (step ST40). This QSY information is "430.000 MHz" in the example shown in FIGS. 5B and 5C. Subsequently, as in step ST35, one character of "" (space) is set (step ST41).

Then, the received message is set (step ST42). This received message is "hello!" In the example shown in FIGS. 5B and 5C. Subsequently, as in step ST35, one character of "" (space) is set (step ST43).

Subsequently, the call sign of the partner station is set (step ST44). This partner station call sign is composed of "de" and a character string indicating the call sign format, and is "de AAA AAA" in the example shown in FIGS. 5B and 5C.

Finally, the line number is set (step ST45). This line number is "{00001" in the example shown in FIGS. 5B and 5C.

(Response message command creation process)
Next, the response message command creation process will be described with reference to FIG. FIG. 6 is a flowchart showing a response message command creation process.

The response message command creation process is a process of assembling a response message. Next to each block shown in FIG. 6, an example of a response message in the process of being assembled is shown.

The response message parameters are set (step ST51). One character ":" (colon) is set as the delimiter (step ST52).

Subsequently, the call sign of the partner station is set (step ST53). The partner station call sign is "AAAAAA" in the example shown in FIG. Similar to step ST52, one character ":" (colon) is set as the delimiter (step ST54).

Subsequently, a response message is set (step ST55). An example of the response message shown in FIG. 6 is “TEST”. Further, another example of the response message is a content indicating that the user of the terminal 100b is away from the terminal 100b at the time when the response message is transmitted. Further, another example of the response message is a content indicating a time point at which the user of the terminal 100b can handle the terminal 100b again.

Subsequently, the response message line number is set (step ST56). An example of the response message line number shown in FIG. 6 is "{00001".

From the above, the response message can be created. It is possible to control the content of the response message to be sent to the E-mail of the terminal 100b.

(Processing to perform QSY function using VoIP)
Next, a process of executing the QSY function using VoIP (Voice over Internet Protocol) will be described with reference to FIG. 7.

As one of the Q codes used internationally in wireless communication, there is QSY used to change the operating voice communication frequency. The QSY function uses this QSY to exchange frequency information of the voice band. In APRS, the QSY function exchanges frequency information by using the AFRS (Automatic Frequency Reporting System) format included in the APRS communication protocol.

A connection is made from the E-mail terminal 40 to the terminal 100b by designating the IP address of the terminal 100b shown in FIG. 2 (step ST61). Subsequently, a TCP connection is made to the TCP number so that command communication can be performed (step ST62). The TCP number is, for example, "TCP: 6000". Subsequently, the frequency is changed to the QSY frequency (step ST63). Subsequently, a UDP connection is made to the UDP number (step ST64). The UDP number is, for example, "UDP: 60001". Subsequently, the voice is packetized (step ST65), voice communication is performed with each other (transmission and reception), and a QSY response is performed (step ST66). Thereby, even if the user of the terminal 100b is away from the terminal 100b, the voice communication frequency used by the terminal 100b can be changed by using the E-mail terminal 40.

(Example of display)
Next, a display example of the display 210, which is an example of the display 10 of the communication device 100, will be described with reference to FIG.

As shown in FIG. 8, the display 210 includes a display area 10a to a display area 10e.

The display 210 displays the reception frequency and the transmission frequency in the display area 10a. When the APRS message is received, the display 210 displays the APRS information as an interrupt screen in the display area 10a.

The display 210 displays a cross key and an “ENT” (decision) key in the middle of the display area 10b. The cross key and the "ENT" key are touch keys and accept operation input by the user. This operation input includes frequency change, character input, menu setting, and the like.

The display 210 displays the numeric keypad in the display area 10c. This numeric keypad is a touch key and accepts operation input by the user. This operation input is a frequency change, a character input, or the like.

The display 210 displays a message being created or created for transmission in the display area 10d. The display 210 displays a "Message SEND" button in the display area 10f. This "Message SEND" button is a touch key and accepts operation input by the user. This operation input is the transmission of a message.

The display 210 displays a "TUNE" button in the display area 10g. This "TUNE" button is a touch key and accepts operation input by the user. This operation input is the execution of QSY.

The display 210 displays QSY information in the display area 10e. This QSY information is the call sign of the partner station and the frequency to be changed.

The present invention is not limited to the above embodiment, and can be appropriately modified without departing from the spirit.

100 Communication device 100a Terminal 100b Terminal 1 Control unit 2 DSP
3 Transmission / reception circuit 4 Antenna 5 Microphone 6 Speaker 7 GNSS module 8 Non-volatile memory 9 LAN port 10, 110, 210 Display (setting screen)
10a-10g Display area 11 PTT switch 12 Operation unit 30 APRS server 40 E-mail terminal 50 Internet 60 Modem M1 Send APRS message M2 Reception confirmation APRS message M3 Automatic response message M4 Forward APRS message ST11-ST26, ST31-ST45, ST51- ST56, ST61-ST66 steps

Claims (4)

Receiver and
A control unit that determines whether the transfer function is enabled or disabled, and
Equipped with automatic forwarding means,
When the receiving unit receives the APRS message transmitted by another communication device and the control unit determines that the transfer function is valid, the automatic transfer means transfers the transfer information including at least the APRS message to APRS. Transfer to the Internet mail address set as the forwarding destination via the gateway station and the APRS server connected to the APRS gateway station.
Communication device. Equipped with an internet line connection to connect to the internet
The control unit includes the Internet line connection destination information for connecting to the Internet line connection unit in the transfer information and transfers the information to the Internet mail address of the transfer destination.
The control unit accepts a remote operation from a transfer destination terminal capable of acquiring the transfer information at the transfer destination Internet mail address to the communication device set based on the Internet line connection destination information.
The communication device according to claim 1. The control unit
When a response message to the APRS message is received from the Internet line connection unit by remote control from the transfer destination terminal, the response message is permitted to be transmitted as an APRS message to another communication device that has transmitted the APRS message.
The communication device according to claim 2. Steps to receive APRS messages sent by other communication devices,
Steps to determine whether the automatic forwarding function is enabled or disabled,
When the APRS message is received and the automatic transfer function is determined to be valid, at least the transfer information including the APRS message is transferred via the APRS gateway station and the APRS server connected to the APRS gateway station. With a step to forward to the Internet email address set as the destination,
Communication device control method.

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