CN110855840A - Mobile phone safety switching system based on combination of network pushing and active scanning - Google Patents

Abstract

The invention discloses a mobile phone safety switching system based on the combination of network pushing and active scanning, which comprises a mobile phone and two special modes built in the mobile phone, namely a safety mode and a life mode; the mobile phone is also internally provided with a mode switching unit, a processor, a storage unit, a monitoring switching unit, a network monitoring module, a base station monitoring unit, a signal receiving unit, a label scanning unit and a data label unit; the invention starts the base station detection unit to detect when the monitoring switching unit correspondingly generates a stable signal, and judges whether the base station is positioned in a special environment or outside the special environment by the base station signal received by the mobile phone; if the fluctuation signal is generated, the label scanning unit is started to scan all the data label groups, and whether the user is in the special environment or not is judged by the scanned data labels.

Description

Mobile phone safety switching system based on combination of network pushing and active scanning

Technical Field

The invention belongs to the field of mobile phone security, relates to a mobile phone mode switching technology, and particularly relates to a mobile phone security switching system based on the combination of network pushing and active scanning.

Background

Patent with publication number CN102970431A discloses a method for switching modes of a mobile phone and a mobile phone, the method includes: receiving a switching instruction for switching the current working mode of the mobile phone into a target mode at an application layer of the current working mode, wherein the target mode comprises an intelligent mode and a non-intelligent mode; when the intelligent mode of the mobile phone is switched to the non-intelligent mode, closing and forbidding the application program functions except the conversation function, wherein the conversation function for bearing the CS domain conversation service is in a normal working state, and loading a non-intelligent mode working interface; and when the non-intelligent mode of the mobile phone is switched into the intelligent mode, the prohibition on the functions of the application program is removed, and an intelligent mode working interface is loaded. The invention provides a working mode for a user, which only keeps the most basic communication function of the intelligent terminal, and can quickly switch the mode to enable the intelligent terminal to be anti-intelligent and return to the most essential communication requirement, thereby obtaining longer standby time and extremely simple operation experience and quickly restoring to the intelligent mode.

But it is not designed for some special environments, such as prisons; using different modes of mobile phone operating systems under different conditions; at present, there are also similar mobile phone operating systems, and the principles thereof are roughly summarized as two, wherein one of them is to determine whether the mobile phone is in a special environment or out of the special environment by using a base station signal received by the mobile phone, and to switch different mobile phone operating systems; the other method is that a mobile phone is used for scanning Bluetooth labels which are preset inside and outside the special environment to judge whether the Bluetooth labels are inside or outside the special environment; however, when the judgment is carried out by means of base station signals, the accuracy depends on the stability of mobile phone signals and the network, and when the network fluctuation is large, the accurate judgment cannot be carried out by means of the base station; in the bluetooth tag mode, different bluetooth tags need to be scanned, which results in large power consumption; the electric quantity stored in the mobile phone battery is limited, so the defect of the mode is large;

in order to solve the technical defect, a good-use mobile phone switching system is provided, and a solution is provided.

Disclosure of Invention

The invention aims to provide a mobile phone safety switching system based on the combination of network pushing and active scanning.

The technical problem to be solved by the invention is as follows:

(1) how to monitor the network stability;

(2) how to select different monitoring methods according to the network stability condition;

(3) how to switch the operation mode of the mobile phone by means of two monitoring methods.

The purpose of the invention can be realized by the following technical scheme:

a mobile phone safety switching system based on the combination of network pushing and active scanning comprises a mobile phone and two special modes built in the mobile phone, namely a safety mode and a life mode, wherein the safety mode is a special mode used by the mobile phone in a special environment; the life mode is a mobile phone operation mode used by a common user; the mobile phone is also internally provided with a mode switching unit, a processor, a storage unit, a monitoring switching unit, a network monitoring module, a base station monitoring unit, a signal receiving unit, a label scanning unit and a data label unit;

wherein, the network monitoring module is used for detecting the communication network speed of the mobile phone and generating a fluctuation signal and a stable signal according to the network speed,

the signal receiving unit is used for receiving signals sent by a base station and communicating by means of the base station, the base station monitoring unit is used for monitoring the base station source of the base station signals received by the signal receiving unit, and the base station monitoring unit stores base station labels in special environments; the network monitoring module transmits a base station measuring signal to the monitoring switching unit when generating a stable signal, and the monitoring switching unit starts the base station monitoring unit to perform base station monitoring analysis and simultaneously closes the label scanning unit when receiving the base station measuring signal transmitted by the network monitoring module; the specific analysis steps are as follows:

the method comprises the following steps: acquiring a received base station signal in a signal receiving unit;

step two: when the base station corresponding to the base station signal is positioned in a special environment, generating a safety signal;

step three: when the base station corresponding to the base station signal is positioned outside the special environment, a life signal is generated;

the base station monitoring unit returns the safety signal and the life signal to the monitoring switching unit when generating the safety signal, and the monitoring switching unit transmits the safety signal and the life signal to the processor;

the network monitoring module transmits a label scanning signal to the monitoring switching unit when generating a fluctuation signal, and the monitoring switching unit starts the label scanning unit and closes the base station monitoring unit;

the data tag unit is a plurality of data tag groups arranged at each exit of the special environment, each exit is provided with one data tag group, and the data tag groups are marked as Bij, i is 1.. n, and j is 1.. m; wherein Bij represents the jth data tag of the ith outlet; the data labels of the same outlet are sequentially arranged at equal intervals, are sequentially set from 1-m according to the j value and from near to far from the outlet, and are arranged on a necessary road where a user leaves a special environment; the method comprises the following steps that a corresponding in-door tag is further arranged in a door of an outlet where each data tag group is located, the in-door tag is arranged in a special environment, the in-door tag is marked as Mi, i is 1.. n, and Mi and Bi are in one-to-one correspondence; the data label can be scanned by the label scanning unit;

the label scanning unit can automatically enter a scanning analysis step when being started, and the specific steps are as follows:

s1: the label scanning unit scans all nearby data labels in real time, and marks the serial numbers of the scanned data labels as scanning serial numbers Qk, wherein k is 1.. n; and Qk ∈ j ═ 1.. m; wherein Q1 represents the first data tag scanned, and Q1 has any of the values of j;

s2: the scanning sequence number Qk is initially determined, and k is continuously substituted into a formula Q of 2_k-Q_k-1Obtaining n-1 sequence number difference values;

s3: when the value of the difference value of all the serial numbers is smaller than zero and is larger than the preset ratio X3, generating a pre-entry state, and judging that the user enters a special environment and generating an entry signal when the corresponding in-door label Mi is scanned in the pre-entry state;

when the corresponding in-door tag Mi is scanned in a life mode state and a non-pre-entry state, judging that the data tag group is invalid, obtaining a corresponding error tag group Bij according to the in-door tag Mi at the moment, and simultaneously generating a checking signal;

s4: when the corresponding in-door label Mi is scanned firstly and the difference values of all the sequence numbers obtained later have the value more than the preset proportion X3 and are more than zero, judging that the user leaves the special environment and generating a leaving signal;

the label scanning unit transmits an entering signal to the monitoring switching unit when generating the entering signal, the monitoring switching unit is used for transmitting the entering signal to the processor, the processor transmits the entering signal to the mode switching unit when receiving the entering signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters a safe mode when receiving the entering signal transmitted by the processor;

the label scanning unit transmits the leaving signal to the monitoring switching unit when generating the leaving signal, the monitoring switching unit is used for transmitting the leaving signal to the processor, the processor transmits the leaving signal to the mode switching unit when receiving the leaving signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters the life mode when receiving the leaving signal transmitted by the processor.

Further, the special environment is a prison.

Further, the determination method for generating the fluctuation signal and the stable signal is as follows:

the method comprises the following steps: acquiring a real-time network speed once by using a network monitoring module at intervals of preset time T1 to obtain a network speed group Vi, i is 1.. n;

step two: acquiring the latest network rate Vn, and then acquiring the first X1 network rates of the Vn, namely Vi, i-n-X1... n;

step three: calculating the average value of the obtained X1+1 network rates, and marking the average value as an adjacent average value J;

step four: using formulas

Calculating to obtain an evaluation stable value W of the network rate;

in the formula | V_i-J | represents the absolute value of Vi-J;

step five: when W is below X2, a stable signal is generated;

step six: when W is greater than X2, a surge signal is generated.

Further, the processor drives the mode switching unit to enter the safe mode when receiving the safe signal transmitted by the monitoring switching unit;

and the processor drives the mode switching unit to enter the life mode when receiving the life signal transmitted by the monitoring switching unit.

Further, the data tag is any one of a bluetooth tag or an RFID tag.

Further, when the label scanning unit generates the leaving signal, the processor automatically acquires the scanned in-door label and the time information, and fuses the in-door label and the time information to form leaving information; the processor is used for transmitting the leaving information to the storage unit for real-time storage.

Further, when the label scanning unit generates an entry signal, the processor automatically acquires the scanned in-door label and the time information, and fuses the in-door label and the time information to form entry information; the processor is used for transmitting the incoming information to the storage unit for real-time storage.

Further, when the tag scanning unit generates the checking signal and the corresponding error tag group Bij, the tag scanning unit transmits the checking signal and the corresponding error tag group Bij to the processor through the monitoring switching unit; the processor is used for transmitting the checking signal and the corresponding error label group Bij to the intelligent terminal through the interaction unit, and the intelligent terminal receives the checking signal and the corresponding error label group Bij transmitted by the interaction unit and reminds a manager to pay attention to checking the error label group Bij.

Furthermore, the intelligent device is a portable device for managers, and specifically is a smart phone.

The invention has the beneficial effects that:

according to the invention, a network monitoring module presets time T1 every interval to obtain a real-time network speed once, so as to obtain a network speed group Vi; acquiring the latest network rate Vn, and then acquiring the first X1 network rates of the Vn, namely Vi; calculating the average value of the obtained X1+1 network rates, and marking the average value as an adjacent average value J; then, whether the network is stable is obtained according to the adjacent mean value J and the network rate group Vi; and generating different signals when the corresponding network fluctuates and is stable;

meanwhile, when the monitoring switching unit correspondingly generates a stable signal, the base station detection unit is started to detect, and whether the base station is located in the special environment or outside the special environment is judged by means of the base station signal received by the mobile phone; if the fluctuation signal is generated, the label scanning unit is started to scan all data label groups, and whether the user is in the special environment or not is judged by means of the scanned data labels;

finally, according to whether the user is in or out of the special environment or not, different modes are selected for operation; meanwhile, the data labels arranged outside the special environment can be monitored according to corresponding rules, and when the data labels have problems, managers can be automatically notified to correct the data labels in time; the invention is simple, effective and easy to use.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a block diagram of the system of the present invention.

Detailed Description

As shown in fig. 1, a mobile phone security switching system based on the combination of network push and active scanning includes a mobile phone and two built-in dedicated modes of the mobile phone, a security mode and a life mode, wherein the security mode is a dedicated mode used by the mobile phone in a special environment and has strong privacy; the life mode is a mode used by a user in life, namely a mobile phone operation mode used by a common user; the special environment can be some high-security places such as prisons and the like;

the mobile phone is also internally provided with a mode switching unit, a processor, a storage unit, a monitoring switching unit, a network monitoring module, a base station monitoring unit, a signal receiving unit, a label scanning unit and a data label unit;

the network monitoring module is used for detecting the communication network speed of the mobile phone, and when the network speed fluctuates, the network speed fluctuation judging method comprises the following steps:

the method comprises the following steps: acquiring a real-time network speed once by using a network monitoring module at intervals of preset time T1 to obtain a network speed group Vi, i is 1.. n;

step two: acquiring the latest network rate Vn, and then acquiring the first X1 network rates of the Vn, namely Vi, i-n-X1... n;

step three: calculating the average value of the obtained X1+1 network rates, and marking the average value as an adjacent average value J;

step four: using formulas

Calculating to obtain an evaluation stable value W of the network rate;

in the formula | V_i-J | represents the absolute value of Vi-J;

step five: when W is below X2, a stable signal is generated;

step six: when W is greater than X2, generating a fluctuation signal;

the signal receiving unit is used for receiving signals sent by a base station and communicating by means of the base station, the base station monitoring unit is used for monitoring the base station source of the base station signals received by the signal receiving unit, and the base station monitoring unit stores base station labels in special environments; the network monitoring module transmits a base station measuring signal to the monitoring switching unit when generating a stable signal, and the monitoring switching unit starts the base station monitoring unit to perform base station monitoring analysis and simultaneously closes the label scanning unit when receiving the base station measuring signal transmitted by the network monitoring module; the specific analysis steps are as follows:

the method comprises the following steps: acquiring a received base station signal in a signal receiving unit;

step two: when the base station corresponding to the base station signal is positioned in a special environment, generating a safety signal;

step three: when the base station corresponding to the base station signal is positioned outside the special environment, a life signal is generated;

the base station monitoring unit returns the safety signal and the life signal to the monitoring switching unit when generating the safety signal, and the monitoring switching unit transmits the safety signal and the life signal to the processor;

the processor drives the mode switching unit to enter a safety mode when receiving the safety signal transmitted by the monitoring switching unit;

the processor drives the mode switching unit to enter a life mode when receiving the life signal transmitted by the monitoring switching unit;

the network monitoring module transmits a label scanning signal to the monitoring switching unit when generating a fluctuation signal, and the monitoring switching unit starts the label scanning unit and closes the base station monitoring unit;

the data tag unit is a plurality of data tag groups arranged at each exit of the special environment, each exit is provided with one data tag group, and the data tag groups are marked as Bij, i is 1.. n, and j is 1.. m; wherein Bij represents the jth data tag of the ith outlet; the data labels of the same outlet are sequentially arranged at equal intervals, are sequentially set from 1-m according to the j value and from near to far from the outlet, and are arranged on a necessary road where a user leaves a special environment; the method comprises the following steps that a corresponding in-door tag is further arranged in a door of an outlet where each data tag group is located, the in-door tag is arranged in a special environment, the in-door tag is marked as Mi, i is 1.. n, and Mi and Bi are in one-to-one correspondence; the data label can be scanned by the label scanning unit; the data tag can be a Bluetooth tag or an RFID tag and the like;

the label scanning unit can automatically enter a scanning analysis step when being started, and the specific steps are as follows:

s1: the label scanning unit scans all nearby data labels in real time, and marks the serial numbers of the scanned data labels as scanning serial numbers Qk, wherein k is 1.. n; and Qk ∈ j ═ 1.. m; wherein Q1 represents the first data tag scanned, and Q1 has any of the values of j;

s2: the scanning sequence number Qk is initially determined, and k is continuously substituted into a formula Q of 2_k-Q_k-1Obtaining n-1 sequence number difference values;

s3: when the value of the difference value of all the serial numbers is smaller than zero and is larger than the preset ratio X3, generating a pre-entry state, and judging that the user enters a special environment and generating an entry signal when the corresponding in-door label Mi is scanned in the pre-entry state;

when the corresponding in-door tag Mi is scanned in a life mode state and a non-pre-entry state, judging that the data tag group is invalid, obtaining a corresponding error tag group Bij according to the in-door tag Mi at the moment, and simultaneously generating a checking signal;

s4: when the corresponding in-door label Mi is scanned firstly and the difference values of all the sequence numbers obtained later have the value more than the preset proportion X3 and are more than zero, judging that the user leaves the special environment and generating a leaving signal;

the label scanning unit transmits an entering signal to the monitoring switching unit when generating the entering signal, the monitoring switching unit is used for transmitting the entering signal to the processor, the processor transmits the entering signal to the mode switching unit when receiving the entering signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters a safe mode when receiving the entering signal transmitted by the processor;

the label scanning unit transmits the leaving signal to the monitoring switching unit when generating the leaving signal, the monitoring switching unit is used for transmitting the leaving signal to the processor, the processor transmits the leaving signal to the mode switching unit when receiving the leaving signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters the life mode when receiving the leaving signal transmitted by the processor.

The processor automatically acquires the scanned in-door label and time information when the label scanning unit generates the leaving signal, and fuses the in-door label and the time information to form leaving information; the processor is used for transmitting the leaving information to the storage unit for real-time storage;

the processor automatically acquires the scanned in-door label and time information when the label scanning unit generates an entry signal, and fuses the in-door label and the time information to form entry information; the processor is used for transmitting the entering information to the storage unit for real-time storage;

when the label scanning unit generates a checking signal and a corresponding error label group Bij, the label scanning unit transmits the checking signal and the corresponding error label group Bij to the processor through the monitoring switching unit; the processor is used for transmitting the checking signal and the corresponding error label group Bij to the intelligent terminal through the interaction unit, and the intelligent terminal receives the checking signal and the corresponding error label group Bij transmitted by the interaction unit and reminds a manager to pay attention to checking the error label group Bij;

the intelligent device is a portable device for managers, and specifically can be a smart phone.

A mobile phone safety switching system based on the combination of network pushing and active scanning firstly monitors a real-time network by means of a network monitoring module and obtains a stable signal and a fluctuation signal under different conditions by combining with relevant rules; when the signal is stabilized, the monitoring switching unit adopts the base station monitoring unit to realize the monitoring inside and outside the special environment, and correspondingly switches different operation modes inside and outside the special environment; the label scanning unit is adjusted to scan by the monitoring switching unit when the fluctuation signal is generated, the special environment is judged when the special environment enters and leaves by means of related rules, different operation modes are switched when the special environment is in different states, and meanwhile, the preset data label can be monitored by means of the corresponding judgment rules, so that the situation of misjudgment caused by the fact that the data label is not repaired in time when the data label is damaged is avoided.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (9)

1. A mobile phone safety switching system based on the combination of network pushing and active scanning comprises a mobile phone and two special modes built in the mobile phone, namely a safety mode and a life mode, wherein the safety mode is a special mode used by the mobile phone in a special environment; the life mode is a mobile phone operation mode used by a common user; the mobile phone is characterized in that a mode switching unit, a processor, a storage unit, a monitoring switching unit, a network monitoring module, a base station monitoring unit, a signal receiving unit, a label scanning unit and a data label unit are also arranged in the mobile phone;

the network monitoring module is used for detecting the communication network speed of the mobile phone and generating a fluctuation signal and a stable signal according to the network speed;

the signal receiving unit is used for receiving signals sent by a base station and communicating by means of the base station, the base station monitoring unit is used for monitoring the base station source of the base station signals received by the signal receiving unit, and the base station monitoring unit stores base station labels in special environments; the network monitoring module transmits a base station measuring signal to the monitoring switching unit when generating a stable signal, and the monitoring switching unit starts the base station monitoring unit to perform base station monitoring analysis and simultaneously closes the label scanning unit when receiving the base station measuring signal transmitted by the network monitoring module; the specific analysis steps are as follows:

the method comprises the following steps: acquiring a received base station signal in a signal receiving unit;

step two: when the base station corresponding to the base station signal is positioned in a special environment, generating a safety signal;

step three: when the base station corresponding to the base station signal is positioned outside the special environment, a life signal is generated;

the base station monitoring unit returns the safety signal and the life signal to the monitoring switching unit when generating the safety signal, and the monitoring switching unit transmits the safety signal and the life signal to the processor;

the network monitoring module transmits a label scanning signal to the monitoring switching unit when generating a fluctuation signal, and the monitoring switching unit starts the label scanning unit and closes the base station monitoring unit;

the data tag unit is a plurality of data tag groups arranged at each exit of the special environment, each exit is provided with one data tag group, and the data tag groups are marked as Bij, i is 1.. n, and j is 1.. m; wherein Bij represents the jth data tag of the ith outlet; the data labels of the same outlet are sequentially arranged at equal intervals, are sequentially set from 1-m according to the j value and from near to far from the outlet, and are arranged on a necessary road where a user leaves a special environment; the method comprises the following steps that a corresponding in-door tag is further arranged in a door of an outlet where each data tag group is located, the in-door tag is arranged in a special environment, the in-door tag is marked as Mi, i is 1.. n, and Mi and Bi are in one-to-one correspondence; the data label can be scanned by the label scanning unit;

the label scanning unit can automatically enter a scanning analysis step when being started, and the specific steps are as follows:

s1: the label scanning unit scans all nearby data labels in real time, and marks the serial numbers of the scanned data labels as scanning serial numbers Qk, wherein k is 1.. n; and Qk ∈ j ═ 1.. m; wherein Q1 represents the first data tag scanned, and Q1 has any of the values of j;

s2: the scanning sequence number Qk is initially determined, and k is continuously substituted into a formula Q of 2_k-Q_k-1Obtaining n-1 sequence number difference values;

s3: when the value of the difference value of all the serial numbers is smaller than zero and is larger than the preset ratio X3, generating a pre-entry state, and judging that the user enters a special environment and generating an entry signal when the corresponding in-door label Mi is scanned in the pre-entry state;

when the corresponding in-door tag Mi is scanned in a life mode state and a non-pre-entry state, judging that the data tag group is invalid, obtaining a corresponding error tag group Bij according to the in-door tag Mi at the moment, and simultaneously generating a checking signal;

s4: when the corresponding in-door label Mi is scanned firstly and the difference values of all the sequence numbers obtained later have the value more than the preset proportion X3 and are more than zero, judging that the user leaves the special environment and generating a leaving signal;

the label scanning unit transmits an entering signal to the monitoring switching unit when generating the entering signal, the monitoring switching unit is used for transmitting the entering signal to the processor, the processor transmits the entering signal to the mode switching unit when receiving the entering signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters a safe mode when receiving the entering signal transmitted by the processor;

the label scanning unit transmits the leaving signal to the monitoring switching unit when generating the leaving signal, the monitoring switching unit is used for transmitting the leaving signal to the processor, the processor transmits the leaving signal to the mode switching unit when receiving the leaving signal transmitted by the monitoring switching unit, and the mode switching unit automatically enters the life mode when receiving the leaving signal transmitted by the processor.

2. The system of claim 1, wherein the special environment is a prison.

3. The system according to claim 1, wherein the method for determining the generation of the fluctuation signal and the stable signal comprises:

the method comprises the following steps: acquiring a real-time network speed once by using a network monitoring module at intervals of preset time T1 to obtain a network speed group Vi, i is 1.. n;

step two: acquiring the latest network rate Vn, and then acquiring the first X1 network rates of the Vn, namely Vi, i-n-X1... n;

step three: calculating the average value of the obtained X1+1 network rates, and marking the average value as an adjacent average value J;

step four: using formulas

Calculating to obtain an evaluation stable value W of the network rate;

in the formula | V_i-J | represents the absolute value of Vi-J;

step five: when W is below X2, a stable signal is generated;

step six: when W is greater than X2, a surge signal is generated.

4. The system according to claim 1, wherein the processor drives the mode switching unit to enter the security mode when receiving the security signal transmitted from the monitoring switching unit;

and the processor drives the mode switching unit to enter the life mode when receiving the life signal transmitted by the monitoring switching unit.

5. The system of claim 1, wherein the data tag is any one of a bluetooth tag and an RFID tag.

6. The mobile phone security switching system based on the combination of network pushing and active scanning as claimed in claim 1, wherein the processor automatically acquires the scanned in-door tag and time information when the tag scanning unit generates the leaving signal, and fuses the in-door tag and the time information to form the leaving information; the processor is used for transmitting the leaving information to the storage unit for real-time storage.

7. The mobile phone security switching system based on the combination of network pushing and active scanning according to claim 1, wherein the processor automatically acquires the scanned in-door tag and time information when the tag scanning unit generates an entry signal, and fuses the in-door tag and the time information to form entry information; the processor is used for transmitting the incoming information to the storage unit for real-time storage.

8. The system of claim 1, wherein the tag scanning unit transmits the verification signal and the corresponding set of faulty tags Bij to the processor through the monitoring switching unit when generating the verification signal and the corresponding set of faulty tags Bij; the processor is used for transmitting the checking signal and the corresponding error label group Bij to the intelligent terminal through the interaction unit, and the intelligent terminal receives the checking signal and the corresponding error label group Bij transmitted by the interaction unit and reminds a manager to pay attention to checking the error label group Bij.

9. The system according to claim 1, wherein the smart device is a portable device for a manager, and particularly a smart phone.