JP2015106800A - Bidirectional communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bidirectional communication system which allows for quick specification of the location of a thing left behind, and quick finding of a child.SOLUTION: A first communication device 11 has a first arithmetic processing unit 111, a first battery 113, a first input module 115, a first output module 117, and a first wireless communication module 119. The first battery 113, first input module 115, first output module 117, and first wireless communication module 119 are connected electrically with the first arithmetic processing unit 111. A second communication device 13 has a second arithmetic processing unit 131, a second battery 133, a second input module 135, a second output module 137, and a second wireless communication module 139.

Description

  The present invention relates to a bidirectional communication system, and more particularly to a bidirectional communication system that provides multi-applications.

  In everyday life, searching for things such as keys, TV remotes, mobile phones, watches, wallets, and glasses is repeated. This wastes time and is very cumbersome. Parents with small children, on the other hand, are worried that their children will be away from their gaze, whether they are at home with the small children or are traveling with them.

  With respect to the above-described problem, Patent Document 1 discloses a bidirectional remote control device having an improved structure. The proposal pushes the call button of the first bidirectional remote control device, transmits the call password from the first bidirectional remote device, and then presses the read button of the second bidirectional remote control device, and then the first bidirectional remote control. The purpose of calling each other is achieved by reading the call password from the device and subsequently transmitting the call password from the second interactive remote control device to the first interactive remote control device. In practice, if the user has a first interactive remote control and attaches the second interactive remote to the watch, the watch cannot press the read button on the second interactive remote control, so the first Not only does the directional remote control device and the second bidirectional remote control device call each other, but the user cannot find the clock.

Taiwan Utility Model No. M353582 Specification

  A main object of the present invention is to provide a two-way communication system that can quickly identify the location of a forgotten item and can quickly find a child.

In order to achieve the above object, a bidirectional communication system according to the present invention includes a first communication device and a second communication device. The first communication device includes a first arithmetic processing unit, a first battery, a first input module, a first output module, and a first wireless communication module. The first battery, the first input module, the first output module, and the first wireless communication module are electrically connected to the first arithmetic processing unit. A first communication device code and a first communication address are stored in the first arithmetic processing unit.
The second communication device includes a second arithmetic processing unit, a second battery, a second input module, a second output module, and a second wireless communication module. The second battery, the second input module, the second output module, and the second wireless communication module are electrically connected to the second arithmetic processing unit. A second communication device code and a second communication address are stored in the second arithmetic processing unit.
The first communication device includes a first communication device code, a first communication address, and a second communication device code by the first input module operating the first arithmetic processing unit, and a signal for calling the second communication device. A certain first type call signal is generated, and the first call signal is transmitted by the first wireless module.
The second communication device receives the first call signal by the second wireless communication module, generates a notification signal based on the second communication device code in the first call signal by the second arithmetic processing unit, and outputs the notification signal A notification signal is transmitted by the module.
The second communication device includes a second communication device code, a second communication address, and a first communication device code by causing the second input module to operate the second arithmetic processing unit, and a signal for calling the first communication device. A certain second type calling signal is generated, and the second type calling signal is transmitted by the second wireless module.
The first communication device receives the second type call signal by the first wireless communication module, generates a notification signal based on the first communication device code in the second type call signal by the first arithmetic processing unit, A notification signal is transmitted by one output module.

  The first input module generates a signal for monitoring the second communication device by activating the first arithmetic processing unit. The first wireless communication module transmits a signal for monitoring the second communication device. The second wireless communication module receives a signal for monitoring the second communication device from the first communication device. The second arithmetic processing unit generates a plurality of response signals within a plurality of response periods based on the signal of the first communication device that monitors the second communication device. The second wireless communication module transmits a response signal. The first wireless communication module is controlled by the first arithmetic processing unit and receives a response signal at a predetermined time. The first arithmetic processing unit generates a warning signal based on the warning condition. A warning signal is emitted by the first output module. The warning condition includes a condition in which the first wireless communication module has not received a response instruction within a predetermined time.

1 is a schematic diagram showing a bidirectional communication system according to an embodiment of the present invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the use condition of the bidirectional | two-way communication system by one Embodiment of this invention. It is a schematic diagram which shows the period of the response time and reception time of the bidirectional | two-way communication system by one Embodiment of this invention.

Hereinafter, a bidirectional communication system according to an embodiment of the present invention will be described with reference to the drawings.
(One embodiment)
As shown in FIG. 1, a bidirectional communication system 10 according to an embodiment of the present invention includes a first communication device 11, a second communication device 13, a third communication device 15, and a fourth communication device 17. The first communication device 11 to the fourth communication device 17 can communicate with each other via a wireless network. In application to the actual situation, the first communication device 11 to the fourth communication device 17 are attached to an object or a child's body in order to quickly find the place where the object is placed or to avoid getting the child lost. Although the present invention is applied as described above, the present invention is not limited to this, and can be applied to other uses.

  The first communication device 11 includes a first arithmetic processing unit 111, a first battery 113, a first input module 115, a first output module 117, and a first wireless communication module 119.

  The second communication device 13 includes a second arithmetic processing unit 131, a second battery 133, a second input module 135, a second output module 137, and a second wireless communication module 139.

  The third communication device 15 includes a third arithmetic processing unit 151, a third battery 153, a third input module 155, a third output module 157, and a third wireless communication module 159.

  The fourth communication device 17 includes a fourth arithmetic processing unit 171, a fourth battery 173, a fourth input module 175, a fourth output module 177, and a fourth wireless communication module 179.

  The first arithmetic processing unit 111 is electrically connected to the first battery 113 to receive the electric energy of the first battery 113, and stores the first communication device code, the general call code, and the first communication address. The second arithmetic processing unit 131 is electrically connected to the second battery 133 to receive the electric energy of the second battery 133, and stores the second communication device code, the general call code, and the second communication address. The third processing unit 151 is electrically connected to the third battery 153 to receive the electric energy of the third battery 153, and stores the third communication device code, the general call code, and the third communication address. The fourth arithmetic processing unit 171 receives the electric energy of the fourth battery 173 by being electrically connected to the fourth battery 173, and stores the fourth communication device code, the general call code, and the fourth communication address. Although the first communication device code to the fourth communication device code are different from the first communication address to the fourth communication address, the general calling codes of the first communication device 11 to the fourth communication device 17 are the same.

  The first input module 115 is electrically connected to the first arithmetic processing unit 111 to activate the first arithmetic processing unit 111. The second input module 135 is electrically connected to the second arithmetic processing unit 131 to activate the second arithmetic processing unit 131. The third input module 155 is electrically connected to the third arithmetic processing unit 151 to activate the third arithmetic processing unit 151. The fourth input module 175 is electrically connected to the fourth arithmetic processing unit 171 to activate the fourth arithmetic processing unit 171. The first input module 115, the second input module 135, the third input module 155, and the fourth input module 175 have a first switch S1, a second switch S2, a third switch S3, a fourth switch S4, and a general call switch ST, respectively. Have. In the present embodiment, the first switch S1, the second switch S2, the third switch S3, the fourth switch S4, and the simultaneous call switch ST are normally open switches. The normal open switch is normally open, and closes and conducts when pressed by an external force or activated by a specific signal, and restores to an open state when the external force or the specific signal disappears.

  The first output module 117 and the first wireless communication module 119 are electrically connected to the first arithmetic processing unit 111. The first wireless communication module 119 is used for receiving and transmitting wireless signals. The second output module 137 and the second wireless communication module 139 are electrically connected to the second arithmetic processing unit 131. The second wireless communication module 139 is used for receiving and transmitting wireless signals. The third output module 157 and the third wireless communication module 159 are electrically connected to the third arithmetic processing unit 151. The third wireless communication module 159 is used for receiving and transmitting wireless signals. The fourth output module 177 and the fourth wireless communication module 179 are electrically connected to the fourth arithmetic processing unit 171. On the other hand, the fourth wireless communication module 179 is used for receiving and transmitting wireless signals. The first output module 119, the second output module 139, the third output module 159, and the fourth output module 179 correspond to communication standards such as IEEE 802.11 standard and Bluetooth profile (Bluetooth® profile).

  From the above description, it is found that the first communication device 11 to the fourth communication device 17 have the same construction and each have a dedicated device code.

  In actual application, the two-way communication system according to the present invention has three modes including an individual call mode (see FIGS. 2A to 2D), a general call mode (see FIGS. 3A to 3C), and a family mode (see FIG. 4). Applicable to.

  In the individual call mode, the first communication device 11 calls the second communication device 13 when the second switch S2 of the first input module 115 is turned on as shown by the black block in FIG. 2A. The first arithmetic processing unit 111 generates an instruction to call the second communication device 13 and transmits the instruction by the first wireless communication module 119. The instruction for calling the second communication device 13 from the first communication device 11 includes a first communication device code, a first communication address, and a second communication device code. Subsequently, the second wireless communication module 139 receives an instruction for calling the second communication device 13 from the first communication device 11. After that, the second arithmetic processing unit 131 generates a notification based on the second communication device code in the instruction to call the second communication device 13 from the first communication device 11, and transmits it by the second output module 137. At this time, the third communication device 15 and the fourth communication device 17 do not operate and maintain a standby state.

  As shown in the black block in FIG. 2B, the first communication device 11 calls the third communication device 15 when the third switch S3 of the first input module 115 becomes conductive. The first arithmetic processing unit 111 generates an instruction to call the third communication device 15 and transmits the instruction by the first wireless communication module 119. The instruction for calling the third communication device 15 from the first communication device 11 includes the first communication device code, the first communication address, and the third communication device code. Subsequently, the third wireless communication module 159 receives an instruction for calling the third communication device 15 from the first communication device 11. After that, the third arithmetic processing unit 151 generates a notification based on the third communication device code in the instruction for calling the third communication device 15 from the first communication device 11, and transmits it by the third output module 157. At this time, the second communication device 13 and the fourth communication device 17 do not operate and maintain a standby state.

  As shown in the black block in FIG. 2C, the first communication device 11 calls the fourth communication device 17 when the fourth switch S4 of the first input module 115 is turned on. The first arithmetic processing unit 111 generates an instruction to call the fourth communication device 17 and transmits the instruction by the first wireless communication module 119. The instruction for calling the fourth communication device 17 from the first communication device 11 includes the first communication device code, the first communication address, and the fourth communication device code. Subsequently, the fourth wireless communication module 179 receives an instruction to call the fourth communication device 17 from the first communication device 11. After that, the fourth arithmetic processing unit 171 generates a notification based on the fourth communication device code in the instruction to call the fourth communication device 17 from the first communication device 11, and transmits it by the fourth output module 177. At this time, the second communication device 13 and the third communication device 15 do not operate and maintain a standby state.

  As shown in the black block in FIG. 2D, when the first switch S1 of the second input module 135 is turned on, the second communication device 13 calls the first communication device 11. The second arithmetic processing unit 131 generates an instruction to call the first communication device 11 and transmits the instruction by the second wireless communication module 139. The instruction for calling the first communication device 11 from the second communication device 13 includes a second communication device code, a second communication address, and a first communication device code. Subsequently, the first wireless communication module 119 receives an instruction for calling the first communication device 11 from the second communication device 13. After that, the first arithmetic processing unit 111 generates a notification based on the first communication device code in the instruction for calling the first communication device 11 from the second communication device 13 and transmits the notification by the first output module 117. At this time, the third communication device 15 and the fourth communication device 17 do not operate and maintain a standby state.

  As described above, in the individual call mode, the switch S 1 of the first communication device 11, the second communication device S 2 of the second communication device 13, the third switch S 3 of the third communication device 15, and the fourth switch of the fourth communication device 17. S4 represents oneself. That is, when the switch is turned on alone, the device does not perform another action.

  From the above description, it has been found that the first switch S1 to the fourth switch S4 of the input module of every device represent the first communication device 11 to the fourth communication device 17, respectively. In other words, the device can call the specific target device by turning on the specific target switch. On the other hand, the device to be identified receives a call instruction, generates a sound, and informs the present location. Every device has a switch that corresponds to another device, so that another device can be called alone. Since the operation method is as described above, the description is omitted.

  In the case of the general call mode, the first communication device 11 is connected to the second communication device 13 and the third communication when the general input switch ST of the first input module 115 is turned on as shown in the black block in FIG. 3A. Call the device 15 and the fourth communication device 17. The first arithmetic processing unit 111 generates a general call instruction and transmits the instruction by the first wireless communication module 119. The general call instruction from the first communication device 11 includes a first communication device code, a first communication address, and a general call code. Subsequently, the second wireless communication module 139, the third wireless communication module 159, and the fourth wireless communication module 179 each receive a general call instruction from the first communication device 11. After that, the second arithmetic processing unit 131, the third arithmetic processing unit 151, and the fourth arithmetic processing unit 171 each generate a notification based on the general calling code in the general calling instruction from the first communication device 11, respectively. Transmission is performed by the second output module 137, the third output module 157, and the fourth output module 177.

  As shown in the black block in FIG. 3B, when the general call switch ST of the second input module 135 is turned on, the second arithmetic processing unit 131 generates a general call instruction, and the second wireless communication module 139 send. The general call instruction from the second communication device 13 includes a second communication device code, a second communication address, and a general call code. Subsequently, the first wireless communication module 119, the third wireless communication module 159, and the fourth wireless communication module 179 each receive a general call instruction from the second communication device 13. After that, the first arithmetic processing unit 111, the third arithmetic processing unit 151, and the fourth arithmetic processing unit 171 each generate a notification based on the general calling code in the general calling instruction from the second communication device 13, respectively. Transmission is performed by the one output module 117, the second output module 157, and the third output module 177.

  As shown in the black block in FIG. 3C, when the general call switch ST of the third input module 155 is turned on, the third arithmetic processing unit 151 generates a general call instruction, and the third wireless communication module 159 send. The general call instruction from the third communication device 15 includes a third communication device code, a third communication address, and a general call code. Subsequently, the first wireless communication module 119, the second wireless communication module 139, and the fourth wireless communication module 179 each receive a general call instruction from the third communication device 15. The first arithmetic processing unit 111, the second arithmetic processing unit 131, and the fourth arithmetic processing unit 171 each generate a notification based on the general call code in the general call instruction from the third communication device 15, and each of the first output Transmission is performed by the module 117, the second output module 137, and the third output module 177.

  Similarly, when the general call switch ST of the fourth input module 175 is turned on, the fourth communication device 17 transmits a general call instruction to the first communication device 11, the second communication device 13, and the third communication device 15. On the other hand, the first communication device 11, the second communication device 13, and the third communication device 15 generate a notification based on the general call code in the general call instruction. As described above, the bidirectional communication system according to the present invention can transmit a notification to the output module of another device by turning on the general call switch of any one of the first communication device 11 to the fourth communication device 17. .

  In the case of the family mode, as shown in FIGS. 4 and 5, in the present embodiment, the second communication device 13 is set as a slave unit, and another device (that is, the first communication device 11, the third communication device 15 and the fourth communication device). The communication device 17) is set as the master unit. In the setting method, the parent device switch and the child device switch on the parent device are turned on, and are maintained for a predetermined time, for example, 5 seconds. Hereinafter, the setting described above with the first communication device 11 as a parent device will be described. As shown in the black block in the figure, the first switch S1 (master switch) and the second switch S2 (slave switch) of the first input module 115 are turned on simultaneously and are turned on for 5 seconds continuously. At this time, the first arithmetic processing unit 111 generates an instruction to monitor the second communication device 13 and transmits the instruction by the first wireless communication module 119. When the second wireless communication module 139 receives an instruction to monitor the second communication device 13 from the first communication device 11, the second arithmetic processing unit 131 generates a response instruction, and the second wireless communication module 139 causes the first communication device 11 to respond. To complete the setting.

  Similarly, if the third communication device 15 and the fourth communication device 17 are set as parent devices by the setting method described above, the first communication device 11, the third communication device 15 and the fourth communication device 17 simultaneously become the parent devices.

As shown in FIG. 5, after the setting of the family mode is completed, cause a plurality of response instructions to the second processing unit 131 in the plurality of response periods T _T, it is transmitted by the second wireless communication module 139. The first wireless communication module 119 is controlled by the first processing unit 111, receives a response command from the second communication device 13 when a predetermined time T _P. When a predetermined time T _P indicates a conductive state exiting in FIG. On the other hand, the first processing unit 111 controls the first wireless communication module 119 within a predetermined time T _P, to stop receiving responses instruction. That is, since the first communication device 11 enters a sleep state, it can reach energy saving.

There is an operation time T1 and a sleep time T2 for each response cycle T _T. If the second arithmetic processing unit 131 issues a response instruction within the operating time T1, the second communication device 13 enters an operating state. If the second arithmetic processing unit 131 stops the response instruction within the sleep time T2, the second communication device 13 enters a sleep state. In the present embodiment, the predetermined time T _P and the sleep time T2 are set to 1 second, and the operation time T1 is set to 3 seconds. When the master unit and the slave unit are within the communication range, the master unit can receive a response instruction from the slave unit when the operation time T1 is reached.

If the first wireless communication module 119 can receive a response indication from the second communication device 13 when a predetermined time T _P, the first communication device 11 (base unit) is without further processing, in response to the next predetermined time Tp Wait to receive instructions. If the first wireless communication module 119 does not receive a response indication from the second communication device 13 even when the predetermined time T _P, the first processing unit 111 causes a warning based on the warning condition, the first output module 117. One of the warning conditions is that the first wireless communication module 119 did not receive a response instruction even after the predetermined time T _P. In other words, when the slave unit moves away from the communication range of the bidirectional communication system according to the present invention, the master unit cannot receive a response instruction from the slave unit, so the master unit generates a warning and the child with the slave unit goes far away. Can be prevented.

  On the other hand, in order to prevent the master unit from misinterpreting that the slave unit is far away, in the present embodiment, the first wireless communication module 119 cannot receive a response instruction even if the predetermined time has elapsed twice. One of the warning conditions. That is, if the parent device (first communication device 11) cannot receive a response instruction from the child device (second communication device 11) twice in succession, it is determined that the child device is not caught. In other words, the fact that the base unit can receive only once while receiving continuously twice does not satisfy the warning condition. If the master unit cannot receive twice during the continuous reception operation, it is determined that the slave unit is not caught. As described above, the bidirectional communication system according to the present invention can prevent erroneous operation when the master unit is in operation and the slave unit is in a sleep state. In the present embodiment, the number of times that the master unit receives the response instruction is not limited to once or twice according to the warning condition, and can be adjusted. The predetermined time, operation time, and sleep time are not limited to a few seconds and can be adjusted.

  Since the second communication device 13 (slave device) must continuously send a response instruction for a long time, the capacity of the second battery 133 is larger than the capacity of the first battery 113, the third battery 153, and the fourth battery 173. large.

  In the present embodiment, the family mode sets the second communication device as a slave unit, but is not limited to this, and another device, such as a first communication device, a third communication device, or a fourth communication device, is selected depending on the situation. You can set the machine. Therefore, the slave unit is not necessarily the second communication device 13. The third communication device 15 and the fourth communication device 17 may be a master unit. Since the setting method and operation are the same as those of the first communication device described above, description thereof is omitted.

  In this embodiment, the 1st output module 115, the 2nd output module 135, the 3rd output module 155, and the 4th output module 175 have any one of a speaker, a light emission source, and a vibration motor. For speakers, notifications and warnings are displayed by voice. In the case of a light source, notifications and warnings are displayed by light. In the case of a vibration motor, notifications and warnings are displayed in a vibration mode. The light emitting source is preferably a light emitting diode (LED), but is not limited thereto. The output module can use a combination of a speaker, a light source and a vibration motor.

  In the present embodiment, four apparatuses will be described as an example, but the present invention is not limited to this. That is, the bidirectional communication system according to the present invention is not limited to four devices depending on the situation, and two devices can be used.

10: Two-way communication system,
11: First communication device,
111: first arithmetic processing unit,
113: first battery,
115: first input module;
117: first output module,
119: First wireless communication module,
13: Second communication device,
131: second arithmetic processing unit;
133: second battery,
135: second input module,
137: Second output module,
139: Second wireless communication module,
15: Third communication device,
151: the third arithmetic processing unit,
153: Third battery,
155: Third input module,
157: Third output module,
159: Third wireless communication module,
17: Fourth communication device,
171: Fourth arithmetic processing unit,
173: Fourth battery,
175: Fourth input module,
177: the fourth output module,
179: Fourth wireless communication module,
S1: First switch,
S2: Second switch,
S3: Third switch
S4: Fourth switch,
ST: Simultaneous call switch,
T _P : predetermined time,
T _T : response cycle,
T1: Operating time,
T2: Stop period.

Claims (11)

A first communication device and a second communication device,
The first communication device includes a first arithmetic processing unit, a first battery, a first input module, a first output module, and a first wireless communication module, the first battery, the first input module, the The first output module and the first wireless communication module are electrically connected to the first arithmetic processing unit, and a first communication device code and a first communication address are stored in the first arithmetic processing unit. ,
The second communication device includes a second arithmetic processing unit, a second battery, a second input module, a second output module, and a second wireless communication module, and the second battery, the second input module, A second output module and the second wireless communication module are electrically connected to the second arithmetic processing unit, and a second communication device code and a second communication address are stored in the second arithmetic processing unit. ,
The first communication device includes the first communication device code, the first communication address, and the second communication device code when the first input module operates the first arithmetic processing unit. Generating a first type call signal that is a signal for calling two communication devices, and transmitting the first call signal by the first wireless module;
The second communication device receives the first call signal by the second wireless communication module, and sends a notification signal based on the second communication device code in the first call signal by the second arithmetic processing unit. Generating and transmitting the notification signal by the second output module,
The second communication device includes the second communication device code, the second communication address, and the first communication device code when the second input module operates the second arithmetic processing unit. Generating a second type calling signal that is a signal for calling one communication device, and transmitting the second type calling signal by the second wireless module;
The first communication device receives the second type call signal by the first wireless communication module, and notifies the first arithmetic processing unit based on the first communication device code in the second type call signal. A bidirectional communication system, wherein a signal is generated and the notification signal is transmitted by the first output module. The first communication device generates a first type monitoring signal that is a signal for monitoring the second communication device by the first input module operating the first arithmetic processing unit, and the first wireless communication module. The first type monitoring signal is transmitted by
The second communication device receives the first monitoring signal from the first communication device by the second wireless communication module, and within a plurality of response periods based on the first monitoring signal by the second arithmetic processing unit. Generating a plurality of first type response finger signals, and transmitting the first type response signals by the second wireless communication module,
The first communication device receives the first type response signal at predetermined intervals by the first wireless communication module controlled by the first arithmetic processing unit, and based on a warning condition by the first arithmetic processing unit. Generating a warning signal, sending the warning signal by the first output module;
2. The bidirectional communication system according to claim 1, wherein the warning condition includes that the first wireless communication module does not receive the response signal within the predetermined period.   The both warning conditions according to claim 2, wherein the warning condition includes that the first wireless communication module does not receive the response signal within a predetermined period that is twice the predetermined period. Communication system. The response cycle includes working time and sleep time,
The first arithmetic processing unit controls the first wireless communication module within the sleep period, stops receiving the response signal,
The second arithmetic processing unit transmits the response signal within the operating time, stops transmitting the response signal within the sleep time,
The two-way communication system according to claim 2, wherein the operation time is several times the sleep time.   The bidirectional communication system according to claim 2, wherein the first battery has a capacity smaller than that of the second battery. The first input module and the second input module both have a first switch and a second switch,
When only the second switch of the first input module is conducted, the first arithmetic processing unit generates the first call signal,
When the first switch and the second switch of the first input module are simultaneously turned on for a predetermined time or more, the first arithmetic processing unit generates the first monitoring signal,
The two-way communication system according to claim 2, wherein when only the second switch of the second input module is turned on, the second arithmetic processing unit generates the second calling finger signal. Further comprising a third communication device,
The third communication device includes a third arithmetic processing unit, a third battery, a third input module, a third output module, and a third wireless communication module, and the third battery, the third input module, A third output module and the third wireless communication module are electrically connected to the third arithmetic processing unit, and the third arithmetic processing unit includes a third communication device code, a third communication address, and a simultaneous The call code is stored,
In the first arithmetic processing unit and the second arithmetic processing unit, a general call code is further stored,
In the first communication device, the first input module includes the first communication device code, the first communication address, and the general call code, when the first input module operates the first arithmetic processing unit. Generating a signal, and transmitting the first type simultaneous call signal by the first wireless communication module;
The second communication device and the third communication device receive the first type simultaneous call signal from the first communication device by the second wireless communication module and the third wireless communication module, and perform the second arithmetic processing. Generating a notification signal based on the general call code in the first type general call signal by the unit and the third arithmetic processing unit, and transmitting the notification signal by the second output module and the third output module,
In the second communication device, the second input module includes the second communication device code, the second communication address, and the general call code by operating the second arithmetic processing unit. Generating a command signal, sending the second type simultaneous call signal by the second wireless communication module,
The first communication device and the second communication device receive the second type simultaneous call signal from the first wireless communication module and the third wireless communication module and the second communication device, and the first arithmetic processing unit And generating a notification signal based on a general call code in the second type simultaneous call signal by the third arithmetic processing unit, and transmitting the notification signal by the first output module and the second output module,
In the third communication device, the third input module includes the third communication device code, the third communication address, and the general call code, when the third input module operates the third arithmetic processing unit. Generating a signal, and sending the third type simultaneous call signal by the third wireless communication module,
The first communication device and the second communication device receive the third type simultaneous call command signal from the third communication device by the first wireless communication module and the second wireless communication module, and perform the first calculation. A notification signal is generated by the processing unit and the second arithmetic processing unit based on the simultaneous call code in the third type simultaneous call signal, and the notification signal is transmitted by the first output module and the second output module The bidirectional communication system according to claim 1, wherein: The third communication device includes the first communication device code, the third communication address, and the first communication device code when the third input module operates the third arithmetic processing unit. A third type calling signal that is a signal for calling a communication device, and a fourth type calling signal that is a signal for calling the second communication device, including the third communication device code, the third communication address, and the second communication device code. Generating the third type calling signal and the fourth type calling signal by the third wireless module,
The first communication device receives the third type call signal by the first wireless communication module, and the first arithmetic processing unit receives the first type call signal from the third type call signal from the third communication device. Generate a notification signal based on the communication device code, send the notification signal by the first output module,
The second communication device receives the third fourth calling signal by the second wireless communication module, and the second arithmetic processing unit receives the second type calling signal from the third type calling signal from the third communication device. Generate a notification signal based on the communication device code, send the notification signal by the second output module,
The first communication device includes the first communication device code, the first communication address, and the third communication device code when the first input module operates the first arithmetic processing unit. A fifth type calling signal that is a signal for calling a communication device is generated, and the fifth type calling signal is transmitted by the first wireless module,
The third communication device receives the fifth type call signal by the third wireless communication module, and a notification signal based on the third communication device code in the fifth call signal by the third arithmetic processing unit. And sending the notification signal by the third output module,
The second communication device includes the second communication device code, the second communication address, and the third communication device code when the second input module activates the second arithmetic processing unit. A sixth type call signal that is a signal for calling a communication device is generated, and the sixth type call signal is transmitted by the second wireless module,
The third communication device receives the sixth type call signal by the third wireless communication module, and notifies the third arithmetic processing unit based on the third communication device code in the sixth type call signal. The bidirectional communication system according to claim 7, wherein a signal is generated and the notification signal is transmitted by the third output module. The first input module, the second input module, and the third input module all have a first switch, a second switch, a third switch, and a general call switch,
When the second switch of the first input module is turned on, the first arithmetic processing unit generates the first type call signal for calling the second communication device,
When the third switch of the first input module is turned on, the first arithmetic processing unit generates the fifth type calling signal for calling the third communication device,
When the general call switch of the first input module is turned on, the first arithmetic processing unit generates the first type general call signal,
When the first switch of the second input module is turned on, the second arithmetic processing unit generates the second type calling signal for calling the first communication device,
When the third switch of the second input module is turned on, the second arithmetic processing unit generates the sixth type call signal for calling the third communication device,
When the general call switch of the second input module is turned on, the second arithmetic processing unit generates the second type general call signal,
When the first switch of the third input module is turned on, the third arithmetic processing unit generates the third type calling signal for calling the first communication device,
When the second switch of the third input module is turned on, the third arithmetic processing unit generates the fourth type call signal instruction for calling the second communication device,
9. The bidirectional communication system according to claim 8, wherein when the general call switch of the third input module is turned on, the third arithmetic processing unit generates the third type general call signal.   The both of the first output module, the second output module, and the third output module each include one of a speaker, a light emitting source, and a vibration motor. Communication system.   The bidirectional communication system according to claim 1, wherein each of the first output module and the second output module includes any one of a speaker, a light source, and a vibration motor.

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