TW201919413A - System and method for monitoring IOT devices based on ringback tone service - Google Patents

Abstract

A system and a method for monitoring IoT devices based on ringback tone service are disclosed. The system comprises an IoT monitoring module, a ringback tone IoT controlling module and a ringback tone module. The IoT monitoring module monitors status of at least one IoT device. The ringback tone IoT controlling module queries the status of the IoT device through the IoT monitoring module via a telecommunication network, and converts the state of the IoT device from text to audio file. The ringback tone module retrieves the audio file from the ringback tone IoT controlling module, and provides the status of the IoT device according to the ringback tone of the audio file.

Description

 System and method for monitoring state of equipment based on incoming call answering  

The present invention relates to a technique for monitoring the state of an associated device, and more particularly to a system and method for monitoring the state of an associated device based on an incoming call.

In recent years, the Internet of Things (IoT) has flourished, and all kinds of Internet of Things monitoring have occurred under the Internet Protocol (IP) environment, but the vast telecommunications network has not been used in IoT equipment. Monitoring area.

At the same time, in the call answering system of the prior art mobile network, the status of the mobile phone can usually only be displayed by ringing the call, but the application of the heterogeneous network cannot be reached. In the service control system of the prior art mobile network, the signal control process between the general sender and the receiver cannot be applied to non-telecom devices (such as IoT devices). In other words, the prior art does not have a cross-border technology that integrates the two domains of the Internet of Things and the telecommunications network.

Therefore, how to integrate the telecommunication network and the Internet of Things and further monitor the state of the IoT device has become a major issue for those skilled in the art.

The present invention provides a system and method for monitoring the status of an IoT device based on an incoming call answering tone, which is capable of providing an IoT device status via a telecommunications network.

The system of the present invention for monitoring the status of an IoT device includes: an IoT monitoring module that monitors the status of at least one IoT device; and an incoming call ringing IoT control module that monitors via the telecommunication network via IoT. The module queries the status of the IoT device to convert the state of the IoT device from text to a sound source file; and an incoming call answering module that captures the audio source file from the call answering IoT control module to make an incoming call according to the audio source file. The answer bell provides the status of the IoT device.

The method for monitoring the state of the IoT device based on the call answering and ringing includes: monitoring the state of at least one IoT device by the IoT monitoring module; querying the IoT by the IoT monitoring module through the telecommunication network through the telecommunication network The status of the device is to convert the state of the IoT device from text to the audio file; and the audio source file from the call answering ring IoT control module is retrieved by the incoming call answering module to provide the IoT device according to the incoming call of the audio file. status.

The above described features and advantages of the invention will be apparent from the description and appended claims. The additional features and advantages of the invention will be set forth in part in the description in the description. The features and advantages of the present invention are realized and attained by the <RTIgt; It is to be understood that both the foregoing general description

1‧‧‧Speaker device

1'‧‧‧System for monitoring the status of IoT devices based on incoming calls

2‧‧‧call answering module

3‧‧‧Call ringing database

4‧‧‧Call ringing tone source archive

5‧‧‧Call ringing IoT (IoT) control module

51, 61‧‧‧ Process Control Module

52, 62‧‧‧ input processing module

53, 63‧‧‧ Output Processing Module

54, 64‧‧‧Interface Access Module

541, 641‧‧VoLTE (Voice Long Term Evolution) unit

542, 642‧‧‧PSTN (Public Telephone Exchange Network) Unit

543, 643‧‧‧PLMN (Public Land Mobile Network) unit

544, 644‧‧‧ Internet unit

55, 65‧‧‧Database Processing Module

56‧‧‧Text-to-speech module

57‧‧‧Message Notification Module

571‧‧‧Event notification unit

572‧‧‧Image/voice notification unit

573‧‧‧Text notification unit

6‧‧‧IoT monitoring module

66‧‧‧IoT device correspondence table

7, 7a to 7n‧‧‧IoT equipment

8‧‧‧Message receiving device

9‧‧‧IoT Message Notification Module

A1 to A8, A1' to A4', B1 to B6‧‧

C1 to C8, C3' to C6', D1 to D8, E1 to E5‧‧ steps

N‧‧‧Telecom network

1 is a schematic diagram of a system for monitoring the state of an object of an object based on an incoming call to answer the bell; and FIG. 2 is a diagram showing an IoT control mode for an incoming call to answer the ring based on the state of the incoming call to monitor the state of the connected device. FIG. 3 is a schematic diagram of an IoT monitoring module in a system for monitoring the state of an object based on an incoming call ringing according to the first embodiment of the present invention; and FIG. 4 is a diagram showing an IoT monitoring module according to FIG. 3 of the present invention. A schematic diagram of the IoT device correspondence table; FIG. 5A and FIG. 5B respectively illustrate different flow charts of the method for monitoring the state of the device based on the incoming call ringing, wherein the FIG. 5A can query and update the state of the IoT device. The image of FIG. 5B can be actively responded by the IoT device to update its state, and both the 5A and 5B images can capture and play the sound source file to provide the state of the IoT device; FIGS. 6A and 6B respectively illustrate the present invention based on the incoming call. A different flow chart of the method for monitoring the state of the device of the object, wherein the figure 6A can set the parameters of the IoT device, and the figure 6B can set the parameters of the plurality of identical IoT devices, and both the 6A and 6B charts can be used. Take and play the audio file The figure provides a state of the IoT device; FIG. 7 is a flow chart of the method for monitoring the state of the device based on the incoming call to answer the ring, wherein the message receiving end can be notified by the push message about the status of the IoT device; FIG. 8 is a flow chart showing a method for monitoring the state of an IOT device based on an incoming call answering bell, wherein the pass code of the IoT device can be set; FIG. 9 is a diagram showing the system for monitoring the state of the IoT device based on the incoming call ringing. FIG. 10 is a schematic diagram showing another embodiment of a system and method for monitoring the state of an object based on an incoming call to answer the bell; and FIG. 11 is a diagram showing the present invention for monitoring an object based on an incoming call to answer the bell. A schematic diagram of yet another embodiment of a system and method of state.

The embodiments of the present invention are described in the following specific embodiments, and those skilled in the art can easily understand other advantages and functions of the present invention by the disclosure of the present disclosure, and can also be implemented by other different embodiments. Or application.

FIG. 1 is a schematic diagram of a system 1' for monitoring the state of an associated device based on an incoming call ringing. As shown in the figure, the system 1' for monitoring the state of the device based on the incoming call to answer the ring may include an IoT monitoring module 6, an incoming call answering IoT control module 5, and an incoming call answering module 2.

The IoT monitoring module 6 can connect and monitor the status of one or more (eg, two or more) IoT devices 7. The call answering IoT control module 5 can query the status of the IoT device 7 via the IoT monitoring module 6 via the telecommunication network N to convert the state of the IoT device 7 from text to a sound source file (not shown).

The incoming call answering module 2 can be connected to the incoming call answering IoT control module 5 to retrieve the audio source file from the incoming call answering IoT control module 5 to provide the status of the IoT device 7 according to the incoming call answering of the audio source file.

The system 1' for monitoring the state of the device based on the incoming call ringing may include the calling device 1 and the calling device 1 (user) may dial the representative number of the IoT device 7 (such as the telephone number in the user's home) to transmit through the telecommunication network. N retrieves the audio source file from the incoming call answering module 2, and then plays the incoming call answering of the audio source file to provide the status of the IoT device 7.

The system 1' for monitoring the state of the device based on the incoming call answering may include an incoming call answering database 3, and the incoming call answering database 3 may be connected to the incoming call answering IoT control module 5 or the incoming call answering module 2, The status of the IoT device 7 stores or updates the ringing conditions of the incoming call to the audio source file.

The system 1' for monitoring the state of the device based on the incoming call answering may include an incoming call answering tone source archive 4, and the incoming call answering tone source archive 4 may be connected to the incoming call answering IoT control module 5 to store the incoming call answering IoT control. The audio source file of module 5.

The system 1' for monitoring the state of the device based on the incoming call answering may include a message receiving device 8 and an IoT message notifying module 9. The message receiving device 8 can be the same device or the same device as the originating device 1, and the IoT message notification module 9 can provide a push notification about the status of the IoT device 7 to the message receiving through the telecommunication network N. End device 8.

The above-mentioned utterance device 1, call answering module 2, call answering IoT control module 5, IoT monitoring module 6, message receiving device 8 and IoT message notification module 9 can communicate with each other through the telecommunication network N, Send a message or receive a message.

The utterance device 1 can be a User Equipment (UE), a communication device, or a mobile device, such as a telephone, a smart phone, or a tablet. The IoT device 7 can be a gas detector, a reed switch, a power switch, a gas flow meter, an audible alarm, a smoke detector, a timer, or a gas shutoff valve as shown in FIG. The telecommunication network N can be a wired network or a wireless network, such as a VoLTE (Voice over Long-Term Evolution) network, a PSTN (Public Switched Telephone Network), and a PLMN (Public Land Mobile). Network, public land mobile network), or the Internet. However, the invention is not limited thereto.

FIG. 2 is a schematic diagram showing the call answering IoT control module 5 in the system 1' for monitoring the state of the device based on the incoming call ringing according to the first embodiment of the present invention. As shown in the figure, the call answering IoT control module 5 can include a flow control module 51, an input processing module 52, an output processing module 53, an interface access module 54, and a database processing module. 55. A text-to-speech module 56 or (and) a message notification module 57.

The flow control module 51 can control the overall processing flow of the incoming call answering IoT control module 5. For example, the flow control module 51 can control the processing flow of the input processing module 52, the output processing module 53, the database processing module 55, the text-to-speech module 56, and/or the message notification module 57.

The input processing module 52 can decode or standardize the input data, so that the flow control module 51 can have a standardized interface when input through different interfaces of the interface access module 54. The output processing module 53 can encode or standardize the output data, so that the flow control module 51 can have a standardized interface when outputted through different interfaces of the interface access module 54.

The interface access module 54 can provide an incoming call answering IoT control module 5 to access a variety of interfaces, and has, for example, VoLTE (Voice Long Term Evolution) unit 541, PSTN (Public Switched Telephone Network) unit 542, PLMN (Public Land Action) Network) unit 543 or internet unit 544, and the like. The VoLTE unit 541 can provide a SIP (Session Initiation Protocol)-based signal control and a Real-time Transport Protocol (RTP) voice detection function. The PSTN unit 542 provides signal control and voice detection functions based on the fixed network ISUP (ISDN User Part), wherein the ISDN is an Integrated Services Digital Network. The PLMN unit 543 provides signal control and voice detection functions based on the mobile network ISUP. Internet unit 544 provides an interface function based on IP (Internet Protocol).

The database processing module 55 can be used to set the incoming call answering database 3 so that the calling device 1 can listen to the status of the IoT device 7 when dialing a specific call.

The Text-to-Speech (TTS) module 56 can use the text-to-speech function to convert the state of the IoT device 7 from the IoT monitoring module 6 from text to a sound source file to store the audio file in the incoming call. The ringing tone source file library 4 is used for the call answering module 2.

The message notification module 57 can provide an alarm broadcast message to the IoT message notification module 9 when the IoT device 7 generates an alarm, so that the IoT message notification module 9 sends the push message to the message receiving device 8. At the same time, the message notification module 57 can have an event notification unit 571, an image/speech notification unit 572 and a text notification unit 573. The event notification unit 571 can provide the notification function of the IoT device 7 regarding the emergency event, the image/voice notification unit 572 can provide the notification function of the IoT device 7 regarding the multimedia event, and the text notification unit 573 can provide the general event notification function of the IoT device 7 regarding the text. .

FIG. 3 is a schematic diagram of the IoT monitoring module 6 in the system 1' for monitoring the state of the device based on the incoming call answering, and FIG. 4 is a diagram showing the IoT monitoring module 6 in the third embodiment of the present invention. A schematic diagram of the IoT device correspondence table 66.

As shown in FIG. 3, the IoT monitoring module 6 can include a process control module 61, an input processing module 62, an output processing module 63, an interface access module 64, and a database processing module 65. Or (and) an IoT device corresponds to Table 66.

The flow control module 61 can control the overall processing flow of the IoT monitoring module 6, store the status of the IoT device 7, report the status of the IoT device 7 (push message), or set the status of the IoT device 7. For example, the flow control module 61 can control the processing flow of the input processing module 62, the output processing module 63, the database processing module 65, or the IoT device correspondence table 66.

The input processing module 62 can decode or standardize the input data, so that the flow control module 61 can have a standardized interface when input through different interfaces of the interface access module 64. The output processing module 63 can encode or standardize the output data, so that the flow control module 61 can have a standardized interface when outputted through different interfaces of the interface access module 64.

The interface access module 64 can provide the IoT monitoring module 6 to access various interfaces, and has, for example, a VoLTE (Voice Long Term Evolution) unit 641, a PSTN (Public Switched Telephone Network) unit 642, and a PLMN (Public Land Mobile Network). Unit 643 or Internet unit 644, etc. The VoLTE unit 641 can provide SIP (Session Initiation Protocol) based signal control and RTP (Instant Transfer Protocol) voice detection functions. The PSTN unit 642 provides signal control and voice detection functions based on a fixed network ISUP (i.e., ISDN user part), wherein the ISDN is an overall serving digital network. The PLMN unit 643 provides signal control and voice detection functions based on the mobile network ISUP. Internet unit 644 provides an interface function based on IP (Internet Protocol).

The database processing module 65 can provide the IoT monitoring module 6 to store the status, history settings, and alarm records of the IoT device 7.

As shown in FIG. 4, the IoT device correspondence table 66 may include, for example, the code of the IoT device, the name of the IoT device, the current state of the IoT device, or the parameters of the IoT device, and the IoT device correspondence table 66 may provide the IoT monitoring module. 6 Monitor, access or set various data of the IoT device 7 through the IoT device correspondence table 66. For example, the code "1" of the IoT device indicates the name of the IoT device "Gas Detector". The current state of the IoT device "1" indicates that the gas detector is in "on detection". The code "2" of the IoT device indicates the name of the IoT device "reed switch". The current state of the IoT device is "0", indicating that the reed switch is in the "door and window closed" for the door and window.

FIG. 5A and FIG. 5B respectively illustrate different flow charts of the method for monitoring the state of the device based on the incoming call to answer, wherein the 5A map can query and update the status of the IoT device 7, and the 5B map can be performed by the IoT device 7 The response is actively updated to update its status, and both the 5A and 5B maps can capture and play the audio file to provide the status of the IoT device 7.

First, in terms of querying and updating the state of the IoT device 7, as shown in steps A1 through A8 of FIG. 5A.

In step A1 and step A2, when the IoT monitoring module 6 monitors the state of at least one IoT device, the IoT control module 5 is queried by the IoT monitoring module 6 through the telecommunication network N (see FIG. 1). The status of the IoT device 7.

In step A3 and step A4, the state of the IoT device 7 is sequentially responded to the IoT monitoring module 6 and the incoming call ringing IoT control module 5.

In step A5, the state of the IoT device 7 is converted from text to a sound source file by the incoming call ringing IoT control module 5 to store the sound source file in the incoming call answering sound source archive 4. In step A6, the storage source file is completed by the incoming call ring source archive 4.

In step A7, the call answering ringing condition of the audio source file is updated by the incoming call ringing IoT control module 5. In step A8, the update of the broadcast condition is completed by the incoming call answering database 6.

Second, in terms of capturing and playing the sound source file to provide the state of the IoT device 7, as shown in steps B1 through B6 of Figure 5A.

In step B1, the calling device 1 (user) dials the representative number of the IoT device 7, such as the telephone number in the home of the user.

In step B2 and step B3, the call answering module 2 retrieves the playing condition of the IoT device 7 from the incoming call answering database 2 to complete the capturing of the playing condition.

In step B4 and step B5, the incoming call answering module 2 retrieves the audio source file from the incoming call answering IoT control module 5 from the incoming ringing tone source archive 4 according to the playing condition of the IoT device 7 to complete the capture. Source file.

In step B6, the caller of the source file is played by the originating device 1 to provide the status of the IoT device 7.

Third, in the aspect in which the IoT device 7 actively responds to update its state, as shown in steps A1' to A4' of FIG. 5B.

In step A1', the IoT device 7 actively responds to its status to the IoT monitoring module 6. In step A2', the state of the IoT device 7 is confirmed by the IoT monitoring module 6.

In step A3', the IoT monitoring module 6 notifies the incoming call answering IoT control module 5 to actively update the state of the IoT device 7. In step A4', the state of receiving the IoT device 7 is confirmed by the incoming call answering IoT control module 5.

In addition, steps A5 to A8 and steps B1 to B6 of FIG. 5B are the same as or similar to those of the above-mentioned FIG. 5A, and therefore will not be repeated.

FIG. 6A and FIG. 6B respectively illustrate different flow charts of the method for monitoring the state of the device based on the incoming call answering, wherein the 6A can set the parameters of the IoT device 7, and the 6B can set a plurality of identical IoTs. The parameters of the device 7, and both the 6A and 6B maps can capture and play the sound source file to provide the status of the IoT device 7.

First, in terms of capturing and playing the sound source file to provide the state of the IoT device 7, as shown in steps B1 through B5 of Figure 6A (or Figure 5A above).

In step B1, the representative number of the IoT device 7 is dialed by the originating device 1 (user).

In step B2 and step B3, the call answering module 2 retrieves the playing condition of the IoT device 7 from the incoming call answering database 2 to complete the capturing of the playing condition.

In step B4 and step B5, the incoming call answering module 2 retrieves the audio source file from the incoming call answering IoT control module 5 from the incoming ringing tone source archive 4 according to the playing condition of the IoT device 7 to complete the capture. Source file.

In step B6, the caller of the source file is played by the originating device 1 to provide the status of the IoT device 7.

Second, in terms of setting the parameters of the IoT device 7 (see FIG. 4), as shown in steps C1 to C5 of FIG. 6A.

In step C1, a physical or virtual Dual-Tone Multi-Frequency (DTMF) button is pressed on the device or operating interface of the self-talking device 1. In step C2, the message of the dual tone multi-frequency button is transmitted by the incoming call answering module 2.

In step C3 and step C4, the call answering IoT control module 5 confirms the authority of the originating device 1 (user) according to the message of the dual tone multi-frequency button, and sets the parameters of the IoT device 7 according to the authority of the calling device 1 (See Figure 4).

In step C5 and step C6, the completed setting message is sequentially transmitted by the IoT device 7 to the IoT monitoring module 6 and the incoming ringing IoT control module 5.

In step C7 and step C8, the incoming call ringing IoT control module 5 sequentially transmits the completed setting message to the incoming call answering module 2 and the calling terminal device 1 (user).

Third, in terms of setting parameters of a plurality of identical IoT devices 7, as shown in steps C3' to C6' of FIG. 6B.

In step C3' and step C4', the call answering IoT control module 5 confirms the authority of the originating device 1 (user) according to the message of the dual tone multi-frequency button, and sets a plurality of the same according to the authority of the calling device 1 The parameters of the IoT device 7 (such as the gas detector of Figure 4).

In step C5' and step C6', the information of the completed setting is sequentially transmitted by the IoT device 7 to the IoT monitoring module 6 and the incoming ringing IoT control module 5.

Similarly, the above steps C3' to C6' may be repeated to repeatedly set parameters of other identical IoT devices 7 (such as the reed switch, power switch or gas flow meter of FIG. 4).

In addition, steps B1 to B6, steps C1 to C2, and C7 to C8 of FIG. 6B are the same as or similar to those of the above-mentioned FIG. 6A, and therefore will not be repeated.

FIG. 7 is a flow chart showing a method for monitoring the state of the device based on the incoming call to answer the ring, wherein the message receiving device 8 can be notified of the status of the IoT device 7 by the push message.

As shown, in step D1, the IoT monitoring module 6 queries the status of the IoT device 7.

In step D2, the IoT device 7 responds to the IoT monitoring module 6 that the status of the IoT device 7 is abnormal.

In step D3, the IoT monitoring module 6 notifies the caller answering IoT control module 5 of the alarm regarding the status of the IoT device 7.

In step D4, the alarm of the status of the IoT device 7 is confirmed by the incoming call ringing IoT control module 5 to the IoT monitoring module 6.

In step D5 and step D6, the alarm of the status of the IoT device 7 is notified by the incoming call ringing IoT control module 5 to the IoT message notification module 9 and the message receiving device 8 in sequence.

In step D7 and step D8, the completion notification of the message receiving end device 8 is sequentially transmitted back to the IoT message notification module 9 and the incoming call ringing IoT control module 5.

FIG. 8 is a flow chart showing a method for monitoring the state of the device of the object based on the incoming call ringing, wherein the pass code of the IoT device 7 can be set.

As shown, in step E1, the IoT device 7 actively initiates its pass code reception management mode.

In step E2, the IoT device 7 is scanned by the IoT monitoring module 6.

In step E3, the IoT device 7 actively requests the passcode from the IoT monitoring module 6.

In step E4, the IoT monitoring module 6 responds to the pass code to the IoT device 7.

In step E5, the IoT device 7 confirms the monitoring of the receiving IoT monitoring module 6.

FIG. 9 is a schematic diagram showing an embodiment of a system and method for monitoring the state of an associated device based on an incoming call ringing in the present invention.

As shown in the figure, for example, the user applies to the telecommunications company for the call answering service to attach the monitoring function of the IoT device, so as to monitor at least one or a plurality of IoT devices in the user's home, such as the IoT device 7a (gas detector), the IoT device. 7b (reed switch) to IoT device 7n (power switch). Next, the telecommunications company configures an IoT monitoring module 6 in the user's home, and the originating device 1 (user) sets its own telephone code number to be the administrator of the IoT monitoring module 6.

When the calling device 1 (user) dials the representative number of the home IoT device (such as the home phone number 031234567) with his own telephone number, if the call answering module 2 determines that the phone number is the manager of the IoT monitoring module 6, Then, the incoming call answering module 2 plays the answering ringing of the corresponding audio source file according to the state of the IoT devices 7a to 7n to the calling device 1 for listening, so that the calling device 1 (user) knows the state of the IoT devices 7a to 7n.

Furthermore, the call answering IoT control module 5 can periodically query the IoT monitoring module 6 for the IoT monitoring module 6 to query the status of the IoT devices 7a to 7n after receiving the query command.

Therefore, the user only needs to configure the IoT monitoring module 6 of the telecommunication company in the home, and dial the representative number of the IoT device (such as the telephone number in the user's home) by the transmitting device 1 to listen to all the IoT in the home through the telecommunication network N. The state of the devices 7a to 7n.

FIG. 10 is a schematic diagram showing another embodiment of a system and method for monitoring the state of an associated device based on an incoming call ringing.

As shown in the figure, for example, the user (the originating device 1) dials the representative number of the IoT device in the home to listen to the incoming call answering of the status of the IoT device, and at this time, the status of the IoT device 7n (power switch) is heard as "power supply". When the user is turned on, the user (the transmitting device 1) can immediately press the IoT device (power switch) code "3" for the dual tone multi-frequency (DTMF) button according to the IoT device correspondence table 66 in FIG. 4, and according to the current IoT Press "0" for the status of the device.

Then, the incoming call answering module 2 can transmit the message of the dual tone multi-frequency (DTMF) button (for example, 30) to the IoT monitoring module 6 via the incoming call ringing IoT control module 5, and is based on the IoT monitoring module 6 The message of the dual tone multi-frequency (DTMF) button changes the state of the IoT device 7n (power switch) to "0" and "power off". At this time, the user (the device 1) can hear the IoT device 7n (power supply). Switch) The incoming call is answered.

11 is a schematic diagram of still another embodiment of a system and method for monitoring the state of an associated device based on an incoming call ringing.

As shown, for example, the user (message receiving device 8) performs gate number registration and binding operations by the IoT application provided by the telecommunications company, and turns on the alarm notifications of the IoT devices 7a to 7n. It should be noted that the message receiving device 8 and the above-mentioned calling device 1 may be the same device or not the same device.

The IoT monitoring module 6 turns on the alarm mode and continuously detects the state of the IoT devices 7a to 7n in the home. At this time, it is found that the IoT device 7a (gas detector) detects that the gas flow is abnormal. Then, the IoT monitoring module 6 transmits the alarm information about the alarm (abnormal) of the IoT device 7a to the IoT message notification module 9 via the call answering IoT control module 5, and the IoT message notification module 9 pushes the message. The notification message receiving device 8 is notified.

It can be seen from the above that the present invention monitors the status of at least one IoT device through the telecommunication network integrated object (IoT) technology, and provides the status of the IoT device by using an incoming call. Thereby, the present invention can integrate the telecommunication network and the Internet of Things to further monitor the state of the device.

At the same time, when the user (the calling device) dials the representative number of the IoT device, the calling device can retrieve the status of the IoT device through the incoming call answering module. Moreover, after the ringback bell is played to play the status of the IoT device, the originating device can set the state of the IoT device by itself in a dual tone multi-frequency (DTMF) manner. In addition, the status of the IoT device can be actively notified to the user (the originating device) through the call answering IoT control module. Thus, the present invention can have the benefit of remotely monitoring IoT devices over a telecommunications network without remoteness.

The above-described embodiments are merely illustrative of the principles, features, and effects of the present invention, and are not intended to limit the scope of the present invention. Any person skilled in the art can recite the above without departing from the spirit and scope of the present invention. The embodiment is modified and changed. Any equivalent changes and modifications made by the disclosure of the present invention should still be covered by the scope of the patent application. Therefore, the scope of protection of the present invention should be as set forth in the scope of the patent application.

Claims (15)

 A system for monitoring the status of an IoT device based on an incoming call answering tone, comprising: an IoT monitoring module that monitors the status of at least one IoT device; and an incoming call ringing IoT control module that transmits the IoT through the telecommunication network The monitoring module queries the status of the IoT device to convert the state of the IoT device from text to a sound source file; and an incoming call answering module that retrieves the audio source file from the call answering IoT control module to The ringing of the source file provides the status of the IoT device.    The system of claim 1, further comprising a calling device, which dials the representative number of the IoT device to retrieve the audio source file from the incoming call answering module, and then plays the ringing of the audio file. To provide the status of the IoT device.    The system of claim 1, further comprising an incoming call answering database connected to the incoming call answering IoT control module or the incoming call answering module to store or update the status according to the status of the IoT device The ringing condition of the incoming call of the audio file.    For example, the system described in claim 1 further includes an incoming call answering tone source file library connected to the incoming call answering IoT control module for storing the audio source file from the incoming call answering IoT control module.    The system of claim 1, further comprising a message receiving device and an IoT message notification module, and the IoT message notification module provides a push message about the status of the IoT device to the message receiving end. Device.    The system of claim 1, wherein the call answering IoT control module has a process control module, a database processing module and a text-to-speech module, wherein the process control module is configured to control the data. The processing flow of the library processing module or the text-to-speech module.    The system of claim 1, wherein the IoT monitoring module has a process control module, a database processing module, and an IoT device correspondence table, wherein the process control module is configured to control the database processing module. Or the processing flow of the IoT device correspondence table.    The system of claim 1, wherein the telecommunications network comprises a Voice Long Term Evolution (VoLTE) network, a Public Switched Telephone Network (PSTN), a Public Land Mobile Network (PLMN), or an Internet.    A method for monitoring the status of an IoT device based on an incoming call answering tone, comprising the steps of: monitoring, by the IoT monitoring module, the status of at least one IoT device; and the IoT monitoring module by the incoming call ringing through the telecommunication network via the IoT monitoring module The group queries the status of the IoT device to convert the status of the IoT device from text to a sound source file; and the call answering module retrieves the audio source file from the call answering IoT control module, according to the audio source file The caller answers the status of the IoT device.    The method of claim 9, further comprising: calling, by the calling device, the representative number of the IoT device to retrieve the audio source file from the incoming call answering module, and then playing the answering ring of the audio source file to Provide the status of the IoT device.    The method of claim 9, further comprising: actively, by the IoT device, the IoT device to the IoT monitoring module, to notify the IoT control module of the IoT monitoring module to actively update the IoT monitoring module. The status of the IoT device.    For example, the method of claim 9 further includes pressing a physical or virtual dual tone multi-frequency (DTMF) button on the self-sending terminal device, so that the call answering IoT control module is based on the dual tone multi-frequency. The button information confirms the authority of the calling terminal, and then sets the parameters of the IoT device according to the authority of the calling terminal.    The method of claim 12, wherein the call answering IoT control module sets parameters of the plurality of identical IoT devices according to the authority of the calling terminal.    The method of claim 9, further comprising: when the IoT monitoring module queries the status of the IoT device as abnormal, the IoT control module sends an alarm of the status of the IoT device, and then The alarm of the status of the IoT device notifies the message receiving device by a push message.    The method of claim 9, further comprising starting a pass code receiving management mode of the IoT device, so that the IoT monitoring module responds to the pass code to the IoT device.