CN205281402U - A device, wearable equipment for data storage and synchronization - Google Patents

Abstract

The utility model discloses a data storage and synchronous device, include: establish wireless connection's wireless transceiver with the terminal, data among the wireless connection control receiving terminal that passes through to establish or to the main control unit of transmitter data in the terminal, the memory of the data of storage receiving and dispatching. The utility model discloses a wearable equipment is still disclosed simultaneously.

Description

Device for data storage and synchronization and wearable equipment

Technical Field

The utility model relates to a data processing technology in the electronic communication field especially relates to a device, wearable equipment that are used for data storage and synchronization.

Background

In recent years, with the rapid development of mobile internet technology, people increasingly depend on various mobile terminals and intelligent devices for life. Although different mobile terminals and intelligent devices have different uses, they have a common feature, namely: both data can be stored and processed. However, during the use of the device, people often encounter the need for data synchronization and backup, for example, documents edited on a home tablet computer need to be referred to on a desktop computer in an office, an address book on a personal smart phone needs to be synchronized to another terminal, and the like.

In response to the similar needs mentioned above, there are currently mainly the following solutions:

1) a conventional Universal Serial Bus (USB) copy and backup method. Obviously, since most of mobile terminals and smart devices do not have USB interfaces, this method can only be used for data transfer between Personal Computers (PCs), and cannot be applied to various mobile terminals and smart devices.

2) Wireless communication technologies based on bluetooth, Wifi, etc. The data can be directly transmitted by using the method, but the method can only be used for point-to-point mutual transmission among the short-distance devices, and cannot realize the synchronization and backup of the remote data; moreover, the problem that the transmission modes between different types of equipment are incompatible exists.

3) Network synchronization and backup technology based on cloud storage. Although the above two methods can solve the problems, the cloud storage is realized by storing data on a network side and logging in a cloud storage device through internet when data synchronization and backup are needed, so that the method also brings risks of unavailable use and possible leakage of important data without network access.

SUMMERY OF THE UTILITY MODEL

In view of this, the embodiment of the present invention is expected to provide a device and a wearable device for data storage and synchronization, which not only can implement data synchronization and backup between various terminals, but also have the characteristics of portability, safety and easy use.

In order to achieve the above purpose, the technical scheme of the utility model is realized like this:

the utility model provides a device for data storage and synchronization, the device includes:

a wireless transceiver for establishing wireless connection with a terminal;

a main controller for controlling the data in the receiving terminal or sending data to the terminal through the established wireless connection;

and a memory for storing the transmitted and received data.

In the above scheme, the apparatus further comprises:

the input and output component is used for realizing human-computer interaction;

a power supply to power the wireless transceiver, the host controller, the memory, and the input-output component.

In the above scheme, the memory includes a nandflash and a norflash.

In the above scheme, the power supply includes a lithium ion battery and a switching power supply or a voltage stabilizer.

In the above scheme, the input/output part includes a power-on key and a three-color LED.

In the above scheme, the wireless connection is a bluetooth connection, a near field communication NFC connection, a radio frequency identification RFID connection, an infrared data standard protocol IrDA connection, an ultra wideband UWB connection, or a zigbee connection.

The utility model also provides a wearable device, the wearable device includes any one of the above-mentioned device for data storage and synchronization and is used for bearing the structure body of the device for data storage and synchronization;

the device for data storage and synchronization is engaged in the structural body.

In the above-described aspect, the structure has a shape conforming to a shape of a wrist.

The embodiment of the utility model provides a be used for data storage and synchronous device, wearable equipment, through set up in the device and establish wireless connection's wireless transceiver with the terminal, when needs synchronous data, wireless connection is established with the terminal to accessible wireless transceiver, receives data or sends data to the terminal from the terminal based on the wireless connection who establishes, and received data can also be saved in the device. Therefore, data synchronization and backup with various terminals can be realized; and moreover, the portable, safe and easy-to-use mobile phone has the characteristics of portability, safety and easy use, and has a good application prospect.

Drawings

Fig. 1 is a schematic view of a structure of a wearable device according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a component structure of a hardware device according to an embodiment of the present invention;

fig. 3 is a schematic flow chart of a method for implementing data storage and synchronization by using the wearable device according to an embodiment of the present invention;

fig. 4 is a schematic diagram of a flow of an implementation principle of a hardware apparatus according to an embodiment of the present invention;

fig. 5 is a schematic view of a flow chart for implementing manual synchronization of terminal application software according to an embodiment of the present invention;

fig. 6 is a schematic diagram of an implementation flow of the automatic synchronization of the terminal application software according to the embodiment of the present invention.

Detailed Description

In order to understand the features and technical contents of the embodiments of the present invention in more detail, the following description is given in conjunction with the accompanying drawings, which are only used for reference and illustration, but not for limitation.

The embodiment of the utility model provides a wearable equipment's component structure is as shown in figure 1, wearable equipment includes: a hardware device 11 and a structural body 12, wherein the hardware device 11 is clamped in the structural body 12; here, the clamping can be completed by arranging a clamping groove and a buckle; the clamping can also be completed by arranging a bulge and a groove; but may be any other mechanism that enables the snap fit. Wherein,

The hardware device 11 is used for realizing data storage and synchronization;

the structural body 12 is used for bearing the hardware device 11; wherein the structure 12 conforms to the shape of the wrist.

The embodiment of the utility model provides a hardware device's component structure is as shown in FIG. 2, and this hardware device includes:

a wireless transceiver 21 for establishing a wireless connection with a terminal;

a main controller 22 for controlling the reception or transmission of data in or to the terminal through the established wireless connection;

a memory 23 for storing data to be transmitted and received;

the memory 23 may be a nandflash or a norflash.

The main controller 22 is electrically connected to the wireless transceiver 21 and the memory 23.

The hardware device further includes: an input/output component 24 for implementing human-computer interaction;

the input/output component 24 includes a power-on key, and a three-color Light Emitting Diode (LED).

The hardware device further includes: a power supply 25 for supplying power to the wireless transceiver 21, the main controller 22, the memory 23, and the input-output unit 24;

the power supply 25 includes a lithium ion battery, and a switching power supply or a voltage regulator.

In the above scheme, the wireless connection may be any one of bluetooth connection, Near Field Communication (NFC), Radio Frequency Identification (RFID), infrared data standard protocol (IrDA), Ultra Wideband (UWB), zigbee connection, and the like.

In this hardware device, the main controller 22 is connected to the wireless transceiver 21, the memory 23, the input/output unit 24, and the power supply 25, respectively.

It should be noted that the main controller 22 is a core part of the hardware device, and may adopt a low power System On Chip (SOC) processor, and a Read Only Memory (ROM) and a Random Access Memory (RAM) are integrated in the SOC.

If two terminals, namely a terminal a and a terminal B, need to synchronize data, the wearable device of the embodiment of the present invention can be used; specifically, the embodiment of the present invention provides a method for implementing data storage and synchronization by using the wearable device, as shown in fig. 3, including the following steps:

step 301: when the terminal A needs to store and synchronize data, the wearable device is close to the terminal A, and wireless connection between the wearable device and the terminal A is established;

Here, a wireless connection is established through a wireless transceiver in the apparatus for enabling data storage and synchronization on the wearable device; the wireless connection is any one of Bluetooth connection, NFC connection, RFID connection, IrDA connection, UWB connection, Zigbee connection and the like.

Step 302: storing data on terminal a in the wearable device based on the established wireless connection;

in particular, the data is stored in a memory in an apparatus on the wearable device for enabling data storage and synchronization.

Step 303: when the terminal B needs to use the data, the wearable device is close to the terminal B, and wireless connection between the wearable device and the terminal B is established;

here, the wireless connection is established in the same manner as in step 301.

Step 304: and sending the data stored in the wearable device to the terminal B.

Furthermore, the synchronous mode can be configured through software, and the functions of reading, writing, modifying and deleting the data file and automatic synchronization can be realized.

The process of implementing data storage and synchronization for the wearable device is further described below by specific application embodiments.

The embodiment of the utility model provides a hardware device's realization principle flow is shown in FIG. 4, and this flow includes following step:

Step 401: after the wearable equipment is started, copying firmware in the hardware device from an on-chip ROM of the main controller to an on-chip RAM, and starting to execute the firmware in the hardware device;

here, the hardware device is a device for implementing data storage and synchronization on the wearable device; the firmware in the hardware device is the hardware component used to manage the operation of the hardware device.

Step 402: initializing a hardware device, and detecting whether the sending and receiving functions of a wireless transceiver in the hardware device and the writing and reading functions of a memory in the hardware device are normal or not;

step 403: judging whether the initialization in the step 402 has errors, if so, entering the step 404, otherwise, entering the step 405;

step 404: flashing a red LED for 20 seconds to prompt a user to maintain, and then entering a sleep mode by the hardware device to finish the current processing flow;

step 405: a wireless transceiver in the hardware device starts to circularly wait for a terminal to establish a connection signal;

step 406: the hardware device receives a connection signal of the terminal, and the two sides try to establish connection;

here, the connection may be various short-range wireless connections, such as: bluetooth connection, NFC connection, RFID connection, IrDA connection, UWB connection, zigbee connection, and the like.

Step 407: judging whether the established wireless connection is successful, if not, returning to the step 405, otherwise, entering the step 408;

step 408: the hardware device sends the data file system information of the hardware device to the terminal and waits for the terminal to send a synchronization instruction;

the data file system information of the hardware device itself includes total storage capacity, usage amount, name, size, modification time, etc. of each data file.

Step 409: judging a synchronous instruction, and entering a step 410 for a read instruction, or entering a step 412;

here, the synchronous instruction is composed of an instruction code and an additional code. The instruction codes are divided into two types, including a reading instruction and a writing instruction; the instruction appended code includes the ID of the data file to be operated and the length of the data file.

Step 410: in the process of reading and sending the data file, the yellow LED flashes to prompt a busy state, and the step 411 is performed after the reading operation is completed;

here, the hardware device obtains the ID of the data file to be read out, searches the data file from the memory, writes the content of the data file into a first-in first-out (FIFO) queue, and simultaneously activates the wireless transceiver to transmit the content of the FIFO to the terminal, according to the received command appending code.

Step 411: waiting for the terminal to return a response mark, if the response is successful, lighting the green LED for 5 seconds by the hardware device, and otherwise, lighting the yellow LED for 5 seconds; after the end, returning to step 408;

step 412: the hardware device judges whether the data file needing to be written can be normally written according to the received instruction additional code, if the data file can be normally written, a writable response mark is sent, and the step 413 is carried out, otherwise, an unwritable response mark is sent, and the step 414 is carried out;

step 413: writing operation, if the writing operation is completed, the hardware device returns a success response signal and simultaneously lights the green LED for 5 seconds, otherwise, returns a failure response signal and lights the yellow LED for 5 seconds; after the end, returning to step 408;

here, the hardware device receives the data file content to the FIFO through the wireless transceiver, performs Cyclic Redundancy Check (CRC) check, and writes the data file content to the data file system after the check is passed.

Step 414: the hardware device can not write, and the yellow LED is lightened for 5 seconds; after this, the process returns to step 408.

In the process of implementing data storage and synchronization, if unexpected interruption occurs, for example, wireless connection is suddenly disconnected in the transmission process, the implementation flow enters an interruption flow, the interruption process cleans up the site, and returns to step 404 to wait for reconnection.

The embodiment of the utility model provides a concrete realization of terminal application software manual synchronization method is shown in figure 5, including following step:

step 501, starting terminal application software, and searching nearby hardware devices according to a uniform equipment identifier;

here, the search may be performed by using a short-range wireless communication method such as bluetooth, NFC, RFID, IrDA, UWB, and zigbee.

Step 502, judging whether an available hardware device exists, if not, prompting a user whether to continue searching, and if so, repeating the step or exiting the application software; otherwise, go to step 503;

step 503, the terminal application software calls a communication interface of the wireless transceiver in the hardware device to start establishing connection with the hardware device;

here, the connection may be various short-range wireless connections, such as: bluetooth connection, NFC connection, RFID connection, IrDA connection, UWB connection, zigbee connection, and the like.

Step 504, judging whether the connection is successfully established, if so, entering step 505, otherwise, returning to step 502;

step 505, according to the data file system information returned by the hardware device, displaying the processed information on a screen, and waiting for further operation of a user;

Step 506, judging the operation taken by the user, wherein the operation that the user can take includes the following operations: firstly, downloading a data file to the local for reference by clicking the data file, and entering step 507; secondly, add new data files (with different file names) to the hardware device, go to step 509; thirdly, changing the existing data file, namely covering the data file with the same file name to the hardware device, and entering step 511; fourthly, deleting the existing data file and entering the step 513;

step 507, reading operation, sending a reading instruction code to the hardware device, and waiting for a returned readable response mark; if so, go to step 508; otherwise, prompting the user that the user is unreadable currently, and returning to the step 505;

step 508: starting a receiving thread to receive the data file sent by the hardware device, returning a successful response mark after successful receiving and passing CRC (cyclic redundancy check) verification, and storing the data file to the local, otherwise, returning a failure response mark and prompting a user to fail reading; after the end, returning to step 505;

step 509, adding new operation, sending a write command to the hardware device, and waiting for a returned writable response flag; if writable, go to step 510; otherwise, prompting the user that the current can not be written, and returning to the step 505;

Step 510, starting a sending thread to read out the specified data file, sending the data file, and entering step 515 after sending is finished;

here, the transmission may be performed by a short-range wireless communication method such as bluetooth, NFC, RFID, IrDA, UWB, and zigbee.

Step 511, modifying the operation, sending a write-in command code to the hardware device, and waiting for a returned writable response mark; if writable, go to step 512; otherwise, prompting the user that the current can not be written, and returning to the step 505;

step 512, prompting the user whether the data needs to be covered, starting a sending thread to read out the specified data file after the user confirms, sending the data file, and entering step 515 after sending is finished;

step 513, deleting the operation, sending a deletion instruction code to the hardware device, and waiting for a returned deletable response flag; if it can be deleted, go to step 514; otherwise, prompting the user that the deletion can not be performed currently, and returning to the step 505;

step 514: firstly, prompting a user whether the deletion is needed, sending a special writing instruction code to a hardware device after the user confirms, and entering step 515 after the sending is finished;

here, the delete operation can be regarded as a special write operation, the instruction code having the data file ID but the file length being 0.

Step 515, after the write operation is completed, the device waits for the hardware device to return a response flag, and prompts the user of the completion of the operation according to the response flag; after that, the process returns to step 505.

The embodiment of the utility model provides a concrete realization of terminal application software automatic synchronization method is shown in figure 6, including following step:

601, after the terminal application software is started, setting the software to be automatically synchronous through a setting item;

step 602, repeatedly searching available hardware devices and establishing connection by a background of the terminal application software, entering step 603 once the connection is successful, otherwise, repeating step 602;

here, the connection may be various short-range wireless connections, such as: bluetooth connection, NFC connection, RFID connection, IrDA connection, UWB connection, zigbee connection, and the like.

Step 603, if a read operation is needed, step 604 is entered, a write operation is needed, step 605 is entered, otherwise step 606 is entered;

here, according to the data file system information returned by the hardware device, the local mirror image data file information is compared, and according to the modification time of the data file, whether the writing and reading operation is needed currently is judged.

Step 604, performing a reading operation, sending a reading instruction code to the hardware device, starting a receiving thread to receive the data file sent by the hardware device, returning a successful response mark after successful reception and passing CRC (cyclic redundancy check), storing the data file to a local mirror image, and otherwise, returning a failed response mark; after the end, returning to step 603;

Step 605, performing write operation, sending a write instruction code to the hardware device, and waiting for a returned writable response mark; if the data file can be written, starting a sending thread to read the specified data file, sending the data file, and returning to the step 603 after the data file is sent;

here, the transmission may be performed by a short-range wireless communication method such as bluetooth, NFC, RFID, IrDA, UWB, and zigbee.

In step 606, after sleeping for 10 minutes, return to step 603.

The embodiment of the utility model provides a be used for data storage and synchronous device, wearable equipment, through set up in the device and establish wireless connection's wireless transceiver with the terminal, when needs synchronous data, wireless connection is established with the terminal to accessible wireless transceiver, receives data or sends data to the terminal from the terminal based on the wireless connection who establishes, and received data can also be saved in the device. Therefore, data synchronization and backup with various terminals can be realized; and moreover, the portable, safe and easy-to-use mobile phone has the characteristics of portability, safety and easy use, and has a good application prospect.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, and any modifications, equivalent replacements, and improvements made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (7)

1. An apparatus for data storage and synchronization, the apparatus comprising:

a wireless transceiver for establishing wireless connection with a terminal;

a main controller for controlling the data in the receiving terminal or sending data to the terminal through the established wireless connection;

a memory for storing the transmitted and received data;

the wireless connection is Bluetooth connection, Near Field Communication (NFC) connection, Radio Frequency Identification (RFID) connection, infrared data standard protocol (IrDA) connection, Ultra Wide Band (UWB) connection and zigbee connection.

2. The apparatus of claim 1, further comprising:

the input and output component is used for realizing human-computer interaction;

a power supply to power the wireless transceiver, the host controller, the memory, and the input-output component.

3. The apparatus of claim 1, wherein the memory comprises a nandflash, a norflash.

4. The apparatus of claim 2, wherein the power supply comprises a lithium ion battery, and a switching power supply or a voltage regulator.

5. The apparatus of claim 2, wherein the input and output components comprise a power-on key, a three-color LED.

6. A wearable device, characterized in that it comprises the apparatus for data storage and synchronization of any of claims 1 to 5, and a structure for carrying the apparatus for data storage and synchronization;

the device for data storage and synchronization is engaged in the structural body.

7. The wearable device of claim 6, wherein the structure conforms to a wrist shape.