CN111601372A

CN111601372A - Data processing device

Info

Publication number: CN111601372A
Application number: CN202010274281.5A
Authority: CN
Inventors: 周文杰
Original assignee: Mobvoi Information Technology Co Ltd
Current assignee: Mobvoi Information Technology Co Ltd; Chumen Wenwen Information Technology Co Ltd
Priority date: 2020-04-09
Filing date: 2020-04-09
Publication date: 2020-08-28
Anticipated expiration: 2040-04-09
Also published as: CN111601372B

Abstract

The invention discloses a data processing device, which comprises an auxiliary system and a switch module: the switch module is used for sending a first control instruction and a second control instruction when the main system is in a non-awakening state, wherein the first control instruction is used for driving the main system to be disconnected from communication with the outside, and the second control instruction is used for driving the auxiliary system to be in communication with the outside; the auxiliary system receives and responds to the second control instruction so as to drive a data receiving module in the auxiliary system to receive external data; the auxiliary system is also used for externally informing the received external data. When data are transmitted to the device from the outside, the auxiliary system processes the outside data, so that the awakening frequency of the main system is reduced, the power consumption of the system is reduced, and the purpose of improving endurance is achieved.

Description

Data processing device

Technical Field

The present invention relates to the field of communications technologies, and in particular, to a data processing apparatus.

Background

In some devices with multiple built-in systems, when a main system is in an un-awakened state, the main system is awakened once an external notification message is received, and frequent awakening of the main system will increase the power consumption of the system.

Disclosure of Invention

The embodiment of the invention provides a data processing device which has the effect of reducing the power consumption of a system by processing a notification message by an auxiliary system when a main system is in a non-awakening state.

The invention provides a data processing device, which comprises an auxiliary system and a switch module: the switch module is used for sending a first control instruction and a second control instruction when the main system is in a non-awakening state, wherein the first control instruction is used for driving the main system to be disconnected from communication with the outside, and the second control instruction is used for driving the auxiliary system to be in communication with the outside; the auxiliary system receives and responds to the second control instruction so as to drive a data receiving module in the auxiliary system to receive external data; the auxiliary system is also used for externally informing the received external data.

In an implementation manner, the auxiliary system is specifically configured to notify the received external data to the outside in a voice broadcast manner, or in a display manner on a screen interface, or in an information transmission manner through a network.

In one embodiment, the auxiliary system comprises a first subsystem and a second subsystem; the data receiving module is installed in the first subsystem; the first subsystem is specifically used for preprocessing data in the received external data to obtain intermediate data which can be commonly applied by the first subsystem and the second subsystem, and transmitting the obtained intermediate data to the second subsystem; the second subsystem is specifically configured to notify the transmitted intermediate data to the outside.

In an implementation, the first subsystem further specifically includes a first hardware interface module and a first service module; the data receiving module is installed in the first hardware interface module; the first hardware interface module is used for transmitting the external data received by the data receiving module to the first service module; and the first service module performs data preprocessing on the external data to obtain intermediate data, and transmits the intermediate data to the second subsystem.

In an embodiment, the first hardware interface module transmits the external data to the first service module through a first hardware abstraction layer; the first service module transmits the intermediate data to the second subsystem specifically through a second hardware abstraction layer.

In one embodiment, the intermediate data is data content; the first service module is specifically configured to perform shelling processing on the external data to obtain data content from the external data.

In one embodiment, the second subsystem comprises a second hardware interface module, a display screen and a second service module; the second service module is used for receiving the intermediate data, performing shell adding processing on the intermediate data to obtain specific data only used by the second subsystem, and transmitting the obtained specific data to the second hardware interface module; and the second hardware interface module is provided with the display screen and displays intermediate data in the specific data according to the received specific data.

In an embodiment, the second service module receives the intermediate data through a third hardware abstraction layer and transmits the specific data to the second hardware interface module through a fourth hardware abstraction layer.

In an implementation manner, the switch module is further specifically configured to drive the auxiliary system to continue receiving and externally notify external data when the auxiliary system is in the operating state and the main system is converted from the non-awake state to the awake state.

In an implementation manner, the data receiving module is specifically one of a bluetooth module, a wireless transceiver module and a wired transceiver module.

In the embodiment of the invention, when data are transmitted to the device from the outside, the auxiliary system is used for processing the outside data, so that the awakening frequency of the main system is reduced, the power consumption of the system is reduced, and the aim of improving endurance is fulfilled.

Drawings

The above and other objects, features and advantages of exemplary embodiments of the present invention will become readily apparent from the following detailed description read in conjunction with the accompanying drawings. Several embodiments of the invention are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which:

in the drawings, the same or corresponding reference numerals indicate the same or corresponding parts.

FIG. 1 is a schematic diagram of a data processing apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a flow chart of an implementation of a data reading method according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a flow chart of implementing a data storage method according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a data reading apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a data storage device according to an embodiment of the present invention;

fig. 6 is a schematic flow chart illustrating an implementation of a data notification method according to an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a data notification apparatus according to an embodiment of the present invention;

fig. 8 is a schematic flow chart illustrating an implementation of a communication handover method according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a communication switching apparatus according to an embodiment of the present invention.

In the figure, 1, a data receiving module; 2. a first subsystem; 3. a second subsystem; 4. a first hardware interface module; 5. a first service module; 6. a first hardware abstraction layer; 7. a second hardware abstraction layer; 8. a second hardware interface module; 9. a display screen; 10. a third hardware abstraction layer; 11. a fourth hardware abstraction layer; 12. a memory.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of a data processing apparatus according to an embodiment of the present invention.

As shown in fig. 1, an aspect of the present invention provides a data processing apparatus, which includes an auxiliary system and a switch module:

the switch module is used for sending a first control instruction and a second control instruction when the main system is in a non-awakening state, wherein the first control instruction is used for driving the main system to be disconnected from the communication connection with the outside, and the second control instruction is used for driving the auxiliary system to be in communication connection with the outside;

the auxiliary system receives and responds to the second control instruction to drive the data receiving module 1 in the auxiliary system to receive the external data;

the auxiliary system is also used for externally informing the received external data.

In this embodiment, the switch module is in communication connection with the main system and the auxiliary system respectively, and is specifically configured to acquire a working state of the main system and control respective communication connection of the main system and the auxiliary system, where the working state includes an awake state and a non-awake state, and the non-awake state further includes a sleep state, and a power-off state.

When the switch module captures that the main system is in a non-awakening state, a first control instruction is sent to the main system, and the first control instruction is used for enabling the main system to be disconnected from the communication connection with the outside. Meanwhile, the switch module sends a second control instruction to the auxiliary system, where the second control instruction is used for the auxiliary system to establish a communication connection with the outside, where the "outside" mentioned in this embodiment is a range other than itself, and is not a range other than the entire device.

The auxiliary system receives and responds to the second control instruction sent by the switch module to drive the data receiving module 1 installed in the auxiliary system to be in communication connection with the outside so as to receive outside data. The auxiliary system finally informs the received external data to the outside.

Therefore, when data are transmitted to the device from the outside, the data are processed through the auxiliary system, so that the awakening frequency of the main system is reduced, the power consumption of the system is reduced, and the purpose of improving endurance is achieved.

Further, the data receiving module 1 is preferably BLE (Bluetooth Low Energy).

Furthermore, each system in the existing multi-system equipment is provided with a BLE module so as to achieve the purpose that any system can keep communication with the outside during working.

In an implementation manner, the switch module is further specifically configured to drive the auxiliary system to continue receiving and externally notify external data when the auxiliary system is in the operating state and the main system is changed from the non-awake state to the awake state.

In this embodiment, when the auxiliary system is in the operating state and the main system is changed from the non-awake state to the awake state, the switch module does not block the communication connection between the auxiliary system and the outside, and still receives the outside data through the auxiliary system, thereby further reducing the power consumption of the main system.

In this embodiment, the auxiliary system may include hardware devices such as a sound generator, a screen, and a wireless transceiver module. After the data receiving module 1 receives the external data, the auxiliary system can inform the external data in a targeted manner according to the type of the external data, wherein the type of the external data comprises image, audio, video, text and the like, and if the external data is the image, video and text data, the external data is informed in a display mode on a screen; if the external data is audio data, the external data is informed in a broadcasting mode through a sounder; the received external data can be informed to the outside in a mode of transmitting to the external equipment again through a network channel. The object informed to the outside can be a person, an animal, an equipment module and the like.

In one embodiment, the auxiliary system comprises a first subsystem 2 and a second subsystem 3;

the data receiving module 1 is installed in the first subsystem 2;

the first subsystem 2 is specifically configured to perform data preprocessing on the received external data to obtain intermediate data that can be commonly applied by the first subsystem 2 and the second subsystem 3, and transmit the obtained intermediate data to the second subsystem 3;

the second subsystem 3 is specifically configured to inform the transmitted intermediate data externally.

In this embodiment, referring to fig. 1 specifically, the first subsystem 2 is preferably an Apollo3+ type single chip microcomputer in this embodiment, the second subsystem 3 is preferably an ST type single chip microcomputer in this embodiment, and the first subsystem 2 and the second subsystem 3 are connected in communication with each other.

The data receiving module 1 is installed in the first subsystem 2, and since different subsystems only process data identified or supported by different subsystems, the external data received by the data receiving module 1 (i.e. BLE in the figure) is subjected to data preprocessing by the first subsystem 2 to obtain intermediate data commonly applied by the first subsystem 2 and the second subsystem 3, and the intermediate data is transmitted to the second subsystem 3, and the second subsystem 3 externally informs the transmitted intermediate data.

In an embodiment, the first subsystem 2 further specifically includes a first hardware interface module 4 and a first service module 5;

the data receiving module 1 is arranged in the first hardware interface module 4;

the first hardware interface module 4 is configured to transmit the external data received by the data receiving module 1 to the first service module 5;

the first service module 5 performs data preprocessing on the external data to obtain intermediate data, and transmits the intermediate data to the second subsystem 3.

In this embodiment, the first hardware Interface module 4 includes hardware or interfaces such as I2C-M (Inter-Integrated circuit master), QSPI/SPI (QSPI: Queued Peripheral Interface), SPI (SPI: Serial Peripheral Interface), DMA (Direct memory access), I2S/PCM (I2S: Inter-IC Sound, Integrated circuit built-In Audio bus, PCM: Pulse-code modulation), and so on, so that hardware or interfaces such as LCD (Liquid Crystal Display ), fuel gauge, Sen (Sensors), BlE (Bluetooth Low Energy, Bluetooth Low power consumption), Audio input (AI, Audio input (FG), and Microphone (Microphone) may be installed on the first hardware Interface module 4. The data receiving module 1 (i.e. BLE in the figure) can be accessed into the first hardware interface module 4 according to its own interface type.

The first hardware interface module 4 is configured to transmit the external data received by the data receiving module 1 to the first service module 5. The first Service module 5 is a processing core of the first subsystem 2, and is configured to process data in the first subsystem 2, and because the first subsystem 2 is preferably a single chip microcomputer of an Apollo3+ type, correspondingly, the first Service module 5 is preferably an Apollo3+ Service module. The first service module 5 is used for carrying out data preprocessing on the external data to obtain intermediate data, and the intermediate data are transmitted to the second subsystem 3 through the first service module 5.

In an embodiment, the first hardware interface module 4 transmits the external data to the first service module 5 through the first hardware abstraction layer 6;

the first service module 5 transmits the intermediate data to the second subsystem 3, in particular via the second hardware abstraction layer 7.

In this embodiment, the first hardware abstraction Layer 6 and the second hardware abstraction Layer 7 (i.e. HAL in the figure) are interface layers between the operating system kernel and the hardware circuit, and the purpose of the interface layers is to abstract the hardware.

In one embodiment, the intermediate data is data content;

the first service module 5 is specifically configured to perform a shelling process on external data to obtain data content from the external data.

In this embodiment, the external data received by the data receiving module 1 includes feature information and data content that can be identified or supported by the first subsystem 2 (mainly, the first hardware interface module 4 or hardware under the first subsystem 2), so that the first service module 5 needs to perform a shelling process on the external data, specifically, delete the feature information from the external data, and only retain the data content.

In an embodiment, the second subsystem 3 comprises a second hardware interface module 8, a display screen 9 and a second service module;

the second service module is used for receiving the intermediate data, performing shell adding processing on the intermediate data to obtain specific data only used by the second subsystem 3, and transmitting the obtained specific data to the second hardware interface module 8;

the second hardware interface module 8 is provided with a display screen 9, and displays the intermediate data in the specific data according to the received specific data.

In this embodiment, the second hardware Interface module 8 includes hardware or interfaces such as I2C-M I2C-M (Inter-Integrated circuit Master), SPI-M (Serial Peripheral Interface), DMA (Direct Memory Access), etc., so that hardware devices such as OLED (Organic Light-Emitting semiconductor), Tou (Touch panel), GPS (Global Positioning System), K (KEY, keyboard), etc. can be installed in the second subsystem 3.

The display screen 9 is preferably an OLED screen, and is installed on the second hardware interface module 8 according to its own interface type, so as to implement the communication connection between the second hardware interface module 8 and the display screen 9.

The second subsystem 3 is preferably an ST-type single chip microcomputer, and correspondingly, the second service module is correspondingly an STs service module and is used for processing data operation in the second subsystem 3. In this embodiment, the second service module is mainly used for performing shell adding processing on the received intermediate data, and specifically includes: the intermediate data is added with feature information that can be recognized or supported by the second hardware interface module 8, hardware, generating specific data. The second service module transmits the generated specific data to the second hardware interface module 8, and the second hardware interface module 8 receives the specific data and displays the intermediate data through the display screen 9.

In an embodiment, the second service module receives intermediate data through the third hardware abstraction layer 10 and transmits specific data to the second hardware interface module 8 through the fourth hardware abstraction layer 11.

In this embodiment, the third hardware abstraction Layer 10 and the fourth hardware abstraction Layer 11 (i.e. HAL in the figure) are interface layers between the operating system kernel and the hardware circuit, and the purpose of the interface layers is to abstract the hardware.

In one embodiment, the data receiving module 1 is one of a bluetooth module, a wireless transceiver module and a wired transceiver module.

In this embodiment, the data receiving module 1 is mainly configured to receive external data, and specifically may be one of a bluetooth module, a wireless transceiver module, and a wired transceiver module, and in fig. 1, the data receiving module 1 is preferably a BLE module (bluetooth low energy).

Fig. 2 is a schematic flow chart illustrating an implementation of a data reading method according to an embodiment of the present invention.

As shown in fig. 2, another aspect of the embodiment of the present invention provides a data reading method applied to an auxiliary system, where the auxiliary system includes a first subsystem 2 and a second subsystem 3 that are communicatively connected to each other, and the method includes:

step 101, when the main system is judged to be in the non-awakening state, the stored data is obtained through the memory 12 in the second subsystem 3;

step 102, transmitting the acquired stored data to the first subsystem 2;

step 103 instructs the first subsystem 2 to read the stored data.

In this embodiment, fig. 1 may be referred to for the structural relationship between the main system and the auxiliary system and the structure of the auxiliary system.

Referring to fig. 1, when the main system is determined to be in the non-wake-up state, the stored data is obtained through the memory 12 in the second subsystem 3, wherein the working state determination process of the main system can be obtained through the switch module; the memory 12 is preinstalled in the second subsystem 3, in particular a NF (Nor Flash, non-volatile Flash technology) based memory, for storing data.

The acquired stored data is then transmitted to the first subsystem 2;

finally, instructing the first subsystem 2 to read the stored data, wherein the reading operation in the embodiment includes displaying and broadcasting the data; if the stored data is audio data, the reading operation is broadcasting; if the stored data is text information, the reading operation at this time is display.

Therefore, when the main system is in a non-awakening state, reading of some data can be achieved through the auxiliary system, and further increase of system power consumption caused by awakening of the main system is avoided.

Further, referring to fig. 1, the second subsystem 3 includes a second service module, and therefore, the specific processes of step 101 and step 102 are as follows: when the main system is determined to be in the non-awake state, the stored data in the memory 12 is obtained through the second service module, and the stored data is transmitted to the first subsystem 2 through the third hardware abstraction layer 10 through the second service module.

In an embodiment, instructing the first subsystem 2 to read the stored data comprises:

instructing the first subsystem 2 to perform shell adding processing on the received stored data to obtain specific data only used by the first subsystem 2;

the first subsystem 2 is instructed to read the resulting specific data.

In this embodiment, the specific process of step 103 is: instructing the first subsystem 2 to perform shell adding processing on the received stored data to obtain specific data only used by the first subsystem 2, specifically: adding feature information which can be recognized or supported by the corresponding first subsystem 2 on the basis of the original data, generating specific data which can be recognized by an interface module or hardware in the first subsystem 2 so that the interface module or hardware can read the specific data.

Further, referring to fig. 1, the first subsystem 2 has a plurality of different reading modes, and different specific data correspond to different reading modes, and corresponding hardware coordination is required, if it is assumed that the extracted stored data is audio data, sound generator hardware is required, and the hardware needs to be installed in the I2S/PCM interface in the first hardware interface module 4. After the acquired stored data is transmitted to the first subsystem 2 in step 101, the first service module 5 of the first subsystem 2 receives the stored data and performs shell adding processing on the stored data to obtain specific data, and then the specific data is transmitted to the sound generator in the second interface module, so that audio data is broadcasted.

Fig. 3 is a schematic flow chart illustrating an implementation of a data storage method according to an embodiment of the present invention.

As shown in fig. 3, another aspect of the embodiment of the present invention is a data storage method applied to an auxiliary system, where the auxiliary system includes a first subsystem 2 and a second subsystem 3 that are communicatively connected to each other, and the method includes:

step 201, when the main system is determined to be in the non-awakening state, the external data is obtained through the data receiving module 1 in the first subsystem 2,

or, when the main system is judged to be in the awakening state, receiving external data from the main system;

step 202, transmitting the acquired external data to the second subsystem 3;

and step 203, instructing the second subsystem 3 to store the transmitted external data into the memory 12.

In this embodiment, referring to fig. 1, when it is determined that the main system is in the non-awake state, the external data is obtained through the data receiving module 1 in the first subsystem 2, or when it is determined that the main system is in the awake state, the external data is received through the slave main system (specifically, the classic bluetooth module in the main system). The working state of the main system may be determined by the switch module, and the data receiving module 1 is mainly used for receiving external data, and may specifically be one of a bluetooth module, a wireless transceiver module, and a wired transceiver module, in this embodiment, the data receiving module 1 is preferably BLE (bluetooth low energy).

The specific process of step 201 is: when the main system is judged to be in a non-awakening state, the switch module enables another auxiliary system to start working, and at the moment, the data receiving module 1 in the first subsystem 2 receives external data; when the host system is determined to be in the wake-up state, the host system is communicatively connected to the memory 12, and external data is received through a receiving module in the host system, such as a classic bluetooth module.

Then, the acquired external data is transmitted to the second subsystem 3, specifically: if the external data is received through the first subsystem 2, the received external data is transmitted to the second subsystem 3 after passing through the first hardware interface module 4, the first hardware abstraction layer 6, the first service module 5 and the second hardware abstraction layer 7 in sequence; if the external data is received by the host system, the external data is transmitted to the memory 12 under the second subsystem 3 by using the output interface of the host system.

And finally, instructing the second subsystem 3 to store the external data obtained by transmission into the memory 12, wherein the specific process is as follows: and the external data is stored in the memory 12 after passing through the third abstraction layer and the second service module in sequence.

In one embodiment, the data receiving module 1 is a bluetooth low energy module;

correspondingly, the external data is obtained through the data receiving module 1 in the first subsystem 2, which includes:

acquiring external data through equipment paired with the low-power-consumption Bluetooth module;

the main system comprises a classic Bluetooth module;

correspondingly, the receiving of the external data from the host system specifically includes:

and acquiring external data from the equipment paired with the classic Bluetooth module in the main system.

In this embodiment, the data receiving module 1 is a low power consumption bluetooth module, and the main system includes a classic bluetooth module; therefore, step 201 specifically includes: and acquiring external data through equipment paired with the low-power-consumption Bluetooth module, and acquiring the external data from equipment paired with a classic Bluetooth module in the main system.

In an embodiment, during bluetooth pairing, the method further includes:

when the main system is judged to be in the awakening state, the low-power-consumption Bluetooth module loses the pairing function through pairing the classic Bluetooth module in the main system and the equipment;

when the main system is judged to be in the non-awakening state, the low-power-consumption Bluetooth module in the auxiliary system is paired with the equipment, and the classical Bluetooth module loses the pairing function.

In the embodiment, the main system and the auxiliary system can only have one side for data receiving Bluetooth pairing, when the main system is judged to be in an awakening state, the classical Bluetooth module in the main system is paired with the equipment to receive external data from the equipment, and at the moment, the low-power Bluetooth module loses the pairing function; when the main system is judged to be in the non-awakening state, the low-power-consumption Bluetooth module in the auxiliary system is paired with the equipment to receive external data from the paired equipment, at the moment, the classical Bluetooth module loses the pairing function, and the on and off of the pairing function can be controlled through the switch module.

In an embodiment, the method further comprises: under the state that the classic Bluetooth module is paired with the equipment, if the main system is switched to the non-awakening state in the awakening state, the classic Bluetooth module is disconnected with the paired equipment;

and instructing the low-power-consumption Bluetooth module to send a pairing request instruction to the equipment to be paired.

In this embodiment, in a state where the classic bluetooth module is paired with the device, if the main system is switched from the awake state to the non-awake state, the switch module controls the classic bluetooth module in the main system to disconnect the communication connection with the paired device, and starts the bluetooth low energy module in the auxiliary system, at this time, the bluetooth low energy module sends a pairing request to the disconnected device, and the disconnected device can establish the communication connection again by responding to the request.

Fig. 4 is a schematic structural diagram of a data reading apparatus according to an embodiment of the present invention.

As shown in fig. 4, another aspect of the embodiment of the present invention provides a data reading apparatus applied to an auxiliary system, the auxiliary system including a first subsystem 2 and a second subsystem 3 communicatively connected to each other, the apparatus including:

a stored data acquiring module 301, configured to acquire stored data through the memory 12 in the second subsystem 3 when it is determined that the host system is in the non-awake state;

a stored data transmission module 302 for transmitting the acquired stored data to the first subsystem 2;

a stored data reading module 303 for instructing the first subsystem 2 to read the stored data.

In this embodiment, fig. 1 may be referred to as a structural relationship diagram of the main system and the auxiliary system.

Referring to fig. 1, when the stored data acquiring module 301 determines that the main system is in the non-awake state, the stored data is acquired through the memory 12 in the second subsystem 3, wherein the working state determining process of the main system can be determined through the switch module; a memory 12 is installed in the second subsystem 3 for storing data.

The acquired stored data is then transmitted to the first subsystem 2 by the stored data transmission module 302;

finally, the stored data reading module 303 instructs the first subsystem 2 to read the stored data, where the reading operation in this embodiment includes displaying and broadcasting the data; if the stored data is audio data, the reading operation is broadcasting; if the stored data is text information, the reading operation at this time is display.

Fig. 5 is a schematic structural diagram of a data storage device according to an embodiment of the present invention.

As shown in fig. 5, another aspect of the present invention provides a data storage device applied to an auxiliary system, where the auxiliary system includes a first subsystem 2 and a second subsystem 3 communicatively connected to each other, and the device includes:

an external data obtaining module 401, configured to obtain external data through the data receiving module 1 in the first subsystem 2 when it is determined that the main system is in the non-wake state,

an external data transmission module 402, configured to transmit the acquired external data to the second subsystem 3;

and an external data storage module 403, configured to instruct the second subsystem 3 to store the transmitted external data in the memory 12.

In this embodiment, referring to fig. 1, first, when the external data obtaining module 401 determines that the main system is in the non-awake state, the external data is obtained through the data receiving module 1 in the first subsystem 2, or when the main system is determined to be in the awake state, the external data is received from the main system. The working state of the main system can be determined by the switch module, the data receiving module 1 is mainly used for receiving external data, and specifically may be one of a bluetooth module, a wireless transceiver module of the wireless transceiver module, and a wired transceiver module of the wired transceiver module, in this embodiment, the data receiving module 1 is preferably BLE (bluetooth low energy).

The external data obtaining module 401 specifically includes: when the main system is judged to be in the non-awakening state, the main system is disconnected from the memory 12 in communication, the switch module enables the auxiliary system to start working, and at the moment, the data receiving module 1 in the first subsystem 2 receives external data; when the host system is determined to be in the wake-up state, the host system is communicatively connected to the memory 12, and receives external data through a receiving module in the host system, such as a classic bluetooth module.

Then, the external data transmission module 402 transmits the acquired external data to the second subsystem 3, specifically: if the external data is received through the first subsystem 2, the received external data is transmitted to the second subsystem 3 after passing through the first hardware interface module 4, the first hardware abstraction layer 6, the first service module 5 and the second hardware abstraction layer 7 in sequence; if the external data is received by the main system, the external data is transmitted to the second subsystem 3 by using the output interface of the main system.

Finally, the external data storage module 403 instructs the second subsystem 3 to store the transmitted external data into the memory 12, which includes the following specific processes: and the external data is stored in the memory 12 after passing through the third abstraction layer and the second service module in sequence.

Another aspect of embodiments of the present invention provides a computer-readable storage medium including a set of computer-executable instructions, which when executed, perform a data reading method.

The computer readable storage medium in embodiments of the present invention comprises a set of computer executable instructions which, when executed, are operable to retrieve stored data via the memory 12 in the second subsystem 3 when it is determined that the host system is in a non-awake state; transmitting the acquired stored data to the first subsystem 2; instructing the first subsystem 2 to read the stored data.

Another aspect of embodiments of the present invention provides a computer-readable storage medium comprising a set of computer-executable instructions, which when executed, perform a data storage method.

The computer readable storage medium in embodiments of the present invention comprises a set of computer executable instructions which, when executed, are operable to retrieve stored data via the memory 12 in the second subsystem 3 when it is determined that the host system is in a non-awake state; transmitting the acquired stored data to the first subsystem 2; instruct the first subsystem 2 to read the stored data

In the embodiment of the present invention, the computer-readable storage medium includes a set of computer-executable instructions, and when the instructions are executed, the data receiving module 1 in the first subsystem 2 is used to obtain external data when the main system is determined to be in the non-wake state, or receive external data from the main system when the main system is determined to be in the wake state; transmitting the acquired external data to the second subsystem 3; instructing the second subsystem 3 to store the transmitted ambient data in the memory 12.

Fig. 6 is a schematic flow chart illustrating an implementation of a data notification method according to an embodiment of the present invention.

As shown in fig. 6, another aspect of the embodiment of the present invention provides a data notification method, which is applied to an auxiliary system, and the method includes:

step 501, when the main system is judged to be in a non-awakening state, receiving external data through an auxiliary system;

step 502, judging whether the received external data is a notification type supported by the auxiliary system;

step 503, if the received external data is determined to be the notification type supported by the auxiliary system, notifying the external data of the data content in the external data through the auxiliary system;

step 504, if it is determined that the received external data is of a notification type that is not supported by the auxiliary system, the external data is externally prompted by the auxiliary system.

In this embodiment, when it is determined that the main system is in the non-awake state, the auxiliary system receives external data, where the non-awake state includes a sleep state, a hibernation state, and a power-off state, and the external data includes a telephone notification, a short message notification, an application notification, and the like.

Then, it is determined whether the received external data is a notification type supported by the auxiliary system, where the supported notification type is usually preset in the system, for example, a short message notification function, a positioning notification function, some cooperative third-party applications, and the like are preset in a mobile phone operating system on the market, the corresponding short message notification type, positioning notification type, and some application notification data are data supported by the auxiliary system, and the other external data is data not supported by the auxiliary system, but may be supported by the main system. Therefore, the specific process of this step may be: and acquiring and judging the notification type of the external data, and comparing the acquired notification type with the notification type preset in the system to judge whether the external data is supported by the system.

And if the received external data is determined to be the notification type supported by the auxiliary system, performing an external notification on the data content in the external data through the auxiliary system, where the external notification specifically is to display the data content on a screen, or to broadcast the data content externally through a sounder, or to transmit the data content to other devices through a network.

If the received external data is judged to be the notification type which is not supported by the auxiliary system, the external data is prompted through the auxiliary system, wherein the external prompt is specifically a message notification prompt displayed on a screen, a message notification prompt broadcasted on a sounder or a light prompt so as to indicate that the receiving of the notification message arrives, but the data content is not displayed. For the notification types which are not supported by the auxiliary system, the user can actively wake up the main system to view or process the notification types according to the notification prompts.

Therefore, when the main system is in a non-awakening state, once external data is received, the notification type can be screened through the auxiliary system and displayed in a targeted mode according to the notification type, the main system cannot be awakened, power consumption of the system is reduced, and endurance time of the system is prolonged.

In an implementation manner, in the process of receiving external data through the auxiliary system when the main system is determined to be in the non-awake state, the method further includes:

and cutting off the communication connection between the main system and the outside so that the auxiliary system receives all the outside data.

In this embodiment, in the process of executing step 501, the communication connection between the main system and the outside is cut off, so as to prevent the data receiving module 1 in the main system from receiving the outside data to wake up the main system, and further enable the auxiliary system to receive all the outside data.

Further, as shown in fig. 1, the steps specifically include: the communication connection between the main system and the outside is cut off by the switch module which is in communication connection with both the main system and the auxiliary system, and the data receiving module 1 in the auxiliary system is driven to receive all the outside messages.

receiving, by an auxiliary system, ambient data, comprising:

receiving external data through a data receiving module 1 of a first subsystem 2;

correspondingly, the externally notifying the data content of the external data in the auxiliary system comprises the following steps:

displaying the data content of the external data on the screen of the second subsystem 3;

correspondingly, carry out the suggestion to the external world to external data in auxiliary system, include:

and carrying out external prompt aiming at external data on the screen of the second subsystem 3.

In this embodiment, as shown in fig. 1, the auxiliary system includes a first subsystem 2 and a second subsystem 3.

With reference to fig. 1, the specific process of step 501 is as follows: the external data is received by the data receiving module 1 of the first subsystem 2. The method specifically comprises the following steps: further, the received ambient data is transferred to the first service module 5 via the first hardware interface module 4 and the first hardware abstraction layer 6. The first service module 5 extracts the data content of the external data and transmits the data content to the second subsystem 3. The second subsystem 3 transmits the data content to the second service module through the third hardware abstraction layer 10, and the second service module is used for judging the notification type of the data content and performing shell processing on the data content.

Correspondingly, the specific process of step 503 is: if the notification type is a supported type, the data content is displayed on the screen through the fourth hardware abstraction layer 11 and the second hardware interface module 8.

The specific process of step 504 is: and if the notification type is an unsupported type, enabling the screen to display message prompt information.

In one embodiment, the externally notifying the data content of the external data in the auxiliary system includes:

and extracting the key display content from the data content, and displaying the extracted key display content on a screen of the auxiliary system.

In this embodiment, in order to apply the method to a small screen or a device with a lower resolution, it is necessary to extract the key display content in the data content, and the extraction method may be implemented by a trained neural network model, where the training of the neural network model includes the following steps:

and taking the related training linguistic data and the corresponding result as the input of the neural network model to obtain an output result, and if the deviation between the output result and the corresponding real result is large, continuing training by using the linguistic data until the training is finished when the deviation between the output result and the corresponding real result is within a preset range.

The highlighted content is then displayed on the screen of the auxiliary system, in particular on the OLED screen in the second subsystem 3, in connection with fig. 1.

In one embodiment, the external prompting for external data in the auxiliary system comprises:

an unread message prompt and icon information corresponding to the data content are displayed on a screen within the auxiliary system.

In this embodiment, step 504 specifically includes: an unread message prompt and icon information corresponding to the data content are displayed on a screen within the auxiliary system. The icon information may be included in the data content, or some icon information corresponding to the type that does not support notification may be stored in advance in the auxiliary system, and the corresponding graph information is extracted from the data content or the corresponding icon information is selected from the system according to the notification type while the unread message prompt is displayed, and the icon information is displayed on the screen.

Fig. 7 is a schematic structural diagram of a data notification apparatus according to an embodiment of the present invention.

As shown in fig. 7, another aspect of the embodiment of the present invention provides a data notification apparatus, which is applied to an auxiliary system, and includes:

an external data receiving module 601, configured to receive external data through an auxiliary system when it is determined that the main system is in a non-awake state;

a notification type determining module 602, configured to determine whether the received external data is a notification type supported by the auxiliary system;

an external notification module 603, configured to notify the external data through the auxiliary system if the notification type determining module 602 determines that the received external data is the notification type supported by the auxiliary system;

the external prompting module 604 is configured to prompt the external data through the auxiliary system if it is determined by the notification type determining module 602 that the received external data is a notification type that is not supported by the auxiliary system.

In this embodiment, when the external data receiving module 601 determines that the main system is in the non-awake state, the external data is received through the auxiliary system, where the non-awake state includes a sleep state, a hibernation state, and a power-off state, and the external data includes a telephone notification, a short message notification, an application notification, and the like.

Then, the notification type determining module 602 determines whether the received external data is a notification type supported by the auxiliary system, where the supported notification type is usually preset in the system, for example, a short message notification function, a positioning notification function, some cooperative third party applications, and the like are preset in a mobile phone operating system in the market, data notified by the corresponding short message notification type, positioning notification type, and some applications is data supported by the auxiliary system, and the other external data is data not supported by the auxiliary system but supported by the main system. Therefore, the specific process of this step may be: and acquiring and judging the notification type of the external data, and comparing the acquired notification type with the notification type preset in the system to judge whether the external data is supported by the system.

Then, if it is determined by the notification type determining module 602 that the received external data is the notification type supported by the auxiliary system, the external notification module 603 is used to notify the data content in the external data to the outside through the auxiliary system, where the external notification is specifically to display the data content on a screen in this embodiment, broadcast the data content to the outside through a sounder, or transmit the data content to other devices through a network.

If the received external data is determined by the notification type determining module 602 to be a notification type that is not supported by the auxiliary system, the external prompt module 604 prompts the external data through the auxiliary system, where the external prompt is, in this embodiment, to display a message notification prompt on a screen, broadcast a message notification prompt on a sound generator, or display a light prompt to indicate that a notification message is received, but does not display data content therein. For notification types that are not supported by the auxiliary system, the user may actively wake up the main system to view or process them.

In an implementation manner, the external data receiving module 601, in the process of receiving the external data through the auxiliary system, is further specifically configured to:

In this embodiment, the external data receiving module 601 is further specifically configured to cut off a communication connection between the main system and the outside during the execution process, so as to prevent the data receiving module 1 in the main system from receiving the external data to wake up the main system, and further enable the auxiliary system to receive all the external data.

In an implementation manner, the external notification module 603 is specifically configured to:

In this embodiment, in order to apply the method to a small screen or a device with a lower resolution, the external notification module 603 is specifically configured to extract the key display content in the data content, where the extraction mode may be implemented by a trained neural network model, and the training of the neural network model includes the following steps:

In an implementation manner, the external prompt module 604 is specifically configured to:

In this embodiment, the external prompt module 604 is specifically configured to: an unread message prompt and icon information corresponding to the data content are displayed on a screen within the auxiliary system. The icon information may be included in the data content, or some icon information corresponding to the type that does not support notification may be stored in advance in the auxiliary system, and the corresponding graph information is extracted from the data content or the corresponding icon information is selected from the system according to the notification type while the unread message prompt is displayed, and the icon information is displayed on the screen.

Another aspect of embodiments of the present invention provides a computer-readable storage medium comprising a set of computer-executable instructions that, when executed, perform a method of data notification.

In an embodiment of the present invention, a computer-readable storage medium includes a set of computer-executable instructions that, when executed, are configured to receive, by an auxiliary system, external data when it is determined that a primary system is in a non-awake state; judging whether the received external data is a notification type supported by the auxiliary system; if the received external data is judged to be the notification type supported by the auxiliary system, the data content in the external data is notified to the outside through the auxiliary system; and if the received external data is judged to be the notification type which is not supported by the auxiliary system, the external data is externally prompted through the auxiliary system.

Fig. 8 is a schematic flow chart illustrating an implementation of a communication handover method according to an embodiment of the present invention.

As shown in fig. 8, another aspect of the present invention provides a communication handover method, where the method includes:

step 701, when the main system is judged to be in a non-awakening state, receiving external data through an auxiliary system;

step 702, judging the notification type of the received external data;

in step 703, if it is determined that the notification type of the received external data is the specific notification type, the host system is awakened, and is instructed to process the external data.

Then, the notification type of the received external data is determined, where the notification type is usually set in advance in the system, for example, a short message notification type, a telephone notification type, a third-party application notification type, and the like.

And then if the received external data notification type is determined to be the specific notification type, waking up the main system and instructing the main system to process the external data. The specific notification type is defined in this embodiment as a notification type that can only be processed by the main system or a specific notification type that is difficult to process by the auxiliary system, and may be set in the system in advance, for example, the types of instant messaging types such as a telephone notification type, a short message notification type, and the like may be used as the specific notification type, and certainly, some third-party applications may be added by the user as the specific notification type. The instructing the main system to process the external data specifically includes: if the specific notification type is a telephone notification type, indicating the main system to carry out operations such as answering and hang up; if the specific notification type is the short message notification type, the host system is instructed to read, delete, reply and the like.

Therefore, the type of the external data is judged, and if the type of the external data is the specific notification type, the external data is handed to the main system to be processed, so that all the external data can be processed.

Further, as shown in fig. 1, when the switch module determines that the main system is in the non-awake state, the data receiving module 1 in the auxiliary system receives external data, transmits the external data to the first service module 5, and determines whether the external data is of the specific notification type by the first service module 5, and if the external data is of the specific notification type, the switch module wakes up the main system and instructs the main system to process the specific notification type.

In an embodiment, the method further comprises:

and if the received notification type of the external data is determined to be the common notification type, indicating the auxiliary system to process the external data.

In this embodiment, if it is determined that the notification type of the received external data is a normal notification type, which is defined as a notification type other than a specific notification type in this embodiment, for example, a calendar notification, an alarm notification, or the like, the auxiliary system is instructed to process the external data.

Further, in connection with fig. 1, the generic notification type is handled in a second service module in the second subsystem 3.

In one embodiment, instructing the auxiliary system to process the external data comprises:

and instructing the auxiliary system to inform the outside of the external data.

In this embodiment, referring to fig. 1, the specific process of "instructing the auxiliary system to process the external data" includes: the method comprises the steps that a data receiving module 1 in a first subsystem 2 is indicated to receive external data, the first subsystem 2 transmits the external data to a second subsystem 3, and the second subsystem 3 informs the outside according to the data content of the external data, wherein the external informing mode can be a bright screen display informing mode and can be used for alarm clock reminding; the system can also be informed in a voice broadcasting mode and can be used for reminding a memorandum; or the mode of external information transmission can be used for transmitting some intermediate data.

In an implementation manner, in the process of waking up the host system and instructing the host system to process the external data, the method further includes:

disconnecting the communication connection between the auxiliary system and the outside;

when the processing of the main system is completed or the main system enters a non-awakening state, the auxiliary system reestablishes communication connection with the outside.

In this embodiment, in the process of waking up the main system and instructing the main system to process external data, the communication connection between the auxiliary system and the outside is disconnected, specifically, with reference to fig. 1, the communication connection between the data receiving module 1 and the outside is disconnected, and after the main system is completed, or when the main system enters a non-wake-up state, the switch module determines that the main system is in the non-wake-up state, and drives the data receiving module 1, that is, the auxiliary system to establish communication connection with the outside again.

In one embodiment, waking up the host system and instructing the host system to process the external data includes:

and awakening the classic Bluetooth module in the main system by using the switch module and indicating the classic Bluetooth module to process external data.

Classic bluetooth module sets up in advance in main system, mainly used and external intercommunication connection. If the external data is judged to be of a specific notification type, and the specific notification type is a call type, the classical Bluetooth module is utilized to perform processing such as answering, hanging up or hanging up on the specific notification type.

As shown in fig. 9, another aspect of the present invention provides a communication switching apparatus, including:

an external data receiving module 801, configured to receive external data through an auxiliary system when it is determined that the main system is in a non-awake state;

a notification type determining module 802, configured to determine a notification type of the received external data;

the first data processing module 803 is configured to wake up the host system and instruct the host system to process the external data when the notification type of the received external data is determined to be the specific notification type by the notification type determining module 802.

In this embodiment, when the external data receiving module 801 determines that the main system is in the non-awake state, the external data is received through the auxiliary system, where the non-awake state includes a sleep state, a hibernation state, and a power-off state, and the external data includes a telephone notification, a short message notification, an application notification, and the like.

Then, the notification type determining module 802 determines the notification type of the received external data, where the notification type is usually preset in the system, for example, a short message notification type, a telephone notification type, a third-party application notification type, and the like.

Then, when the notification type of the received external data is determined to be a specific notification type by the notification type determining module 802, the first data processing module 803 wakes up the host system and instructs the host system to process the external data. The specific notification type is defined in this embodiment as a notification type that can only be processed by the main system or a specific notification type that is difficult to process by the auxiliary system, and may be set in the system in advance, for example, the types of instant messaging types such as a telephone notification type, a short message notification type, and the like may be used as the specific notification type, and certainly, some third-party applications may be added by the user as the specific notification type. The instructing the main system to process the external data specifically includes: if the specific notification type is a telephone notification type, indicating the main system to carry out operations such as answering and hang up; if the specific notification type is the short message notification type, the host system is instructed to read, delete, reply and the like.

In one embodiment, the apparatus further comprises:

the second data processing module 804 is configured to instruct the auxiliary system to process the external data if it is determined that the notification type of the received external data is the normal notification type.

In this embodiment, if the notification type of the received external data is determined to be a normal notification type by the notification type determining module 802, the auxiliary system is instructed to process the external data by the second data processing module 804, where the normal notification type is defined as a notification type other than a specific notification type in this embodiment, such as a calendar notification, an alarm notification, and the like.

In an implementation manner, the second data processing module 804 is specifically configured to:

In this embodiment, as shown in fig. 1, the second data processing module 804 is specifically configured to: the method comprises the steps that a data receiving module 1 in a first subsystem 2 is indicated to receive external data, the first subsystem 2 transmits the external data to a second subsystem 3, and the second subsystem 3 informs the outside according to the data content of the external data, wherein the external informing mode can be a bright screen display informing mode and can be used for alarm clock reminding; the system can also be informed in a voice broadcasting mode and can be used for reminding a memorandum; or the mode of external information transmission can be used for transmitting some intermediate data.

In an implementation manner, the first data processing module 803 is specifically configured to:

Another aspect of embodiments of the present invention provides a computer-readable storage medium comprising a set of computer-executable instructions, which when executed, perform a method for communication handover.

In an embodiment of the present invention, a computer-readable storage medium includes a set of computer-executable instructions that, when executed, are configured to receive, by an auxiliary system, external data when it is determined that a primary system is in a non-awake state; judging the notification type of the received external data; and if the received external data notification type is determined to be the specific notification type, waking up the main system and indicating the main system to process the external data.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. A data processing apparatus, characterized in that the apparatus comprises an auxiliary system and a switch module:

the switch module is used for sending a first control instruction and a second control instruction when the main system is in a non-awakening state, wherein the first control instruction is used for driving the main system to be disconnected from communication with the outside, and the second control instruction is used for driving the auxiliary system to be in communication with the outside;

the auxiliary system receives and responds to the second control instruction so as to drive a data receiving module (1) in the auxiliary system to receive outside data;

2. The device according to claim 1, wherein the auxiliary system is specifically configured to notify the received external data to the outside in a voice broadcast manner, or in a display manner on a screen interface, or in a manner of information transmission via a network.

3. The device according to claim 1, characterized in that the auxiliary system comprises a first subsystem (2) and a second subsystem (3);

the data receiving module (1) is installed in the first subsystem (2);

the first subsystem (2) is specifically configured to perform data preprocessing on the received external data to obtain intermediate data that can be commonly applied by the first subsystem (2) and the second subsystem (3), and transmit the obtained intermediate data to the second subsystem (3);

the second subsystem (3) is used in particular for externally informing the transmitted intermediate data.

4. The device according to claim 3, characterized in that said first subsystem (2) further comprises in particular a first hardware interface module (4) and a first service module (5);

the data receiving module (1) is installed in the first hardware interface module (4);

the first hardware interface module (4) is used for transmitting the external data received by the data receiving module (1) into the first service module (5);

the first service module (5) performs data preprocessing on the external data to obtain intermediate data, and transmits the intermediate data to the second subsystem (3).

5. The arrangement according to claim 4, characterized in that the first hardware interface module (4) transmits the ambient data into the first service module (5) in particular through a first hardware abstraction layer (6);

the first service module (5) transmits the intermediate data to the second subsystem (3), in particular via a second hardware abstraction layer (7).

6. The apparatus of claim 4, wherein the intermediate data is data content;

the first service module (5) is specifically configured to perform a shelling process on the external data to obtain data content from the external data.

7. The device according to claim 3, characterized in that said second subsystem (3) comprises a second hardware interface module (8), a display screen (9) and a second service module;

the second service module is used for receiving the intermediate data, performing shell processing on the intermediate data to obtain specific data only used by the second subsystem (3), and transmitting the obtained specific data to the second hardware interface module (8);

the second hardware interface module (8) is provided with the display screen (9), and displays intermediate data in the specific data according to the received specific data.

8. The arrangement according to claim 7, characterized in that said second service module receives said intermediate data through a third hardware abstraction layer (10) and transmits said specific data to said second hardware interface module (8) through a fourth hardware abstraction layer (11).

9. The device according to claim 1, wherein the switch module is further specifically configured to drive the auxiliary system to continue receiving and externally notify external data when the auxiliary system is in the operating state and the main system is changed from the non-wake state to the wake state.

10. Device according to claim 1, characterized in that the data receiving module (1) is in particular one of a bluetooth module, a wireless transceiver module and a wired transceiver module.