BE1028122B1 - Advanced physical key-based control system and method for quick access to a terminal - Google Patents

Abstract

The present invention discloses a physical key based enhanced control system and method for quick access to a terminal, the system comprising a physical key module, a microprocessor, a wireless communication module and a power module, and wherein the physical key module is electrically connected to the microprocessor , and wherein one end of the wireless communication module is electrically connected to the microprocessor and the other end is communicatively connected to a terminal having a corresponding communication function, and wherein the power supply module is electrically connected to the microprocessor. The system interacts with the terminal device through the wireless communication module, an extended control function is provided through a module of the physical button, the user can press the physical button module to conveniently control the terminal device and thus realize a corresponding function under the In order not to impair the normal operation of the terminal, the requests for the touch control and the physical buttons are taken into account at the same time. In the method, rapid access to a terminal device is realized using an above extended control system, so that part of the functions on the terminal device can be controlled and realized more quickly in order to improve the control experience of the user.

Description

'BE2020 / 5874 Extended control system and method based on physical buttons for quick access to a terminal

TECHNICAL FIELD The present invention relates to the technical field of extended control of the terminal and wireless communication, in particular to an extended control system based on physical keys and a method for fast access to a terminal.

BACKGROUND ART At present, touch screen technology is advancing and virtual buttons have become the main part for controlling a cellular phone. There are fewer and fewer physical buttons on cell phones. However, as the internal functions of cell phones continue to increase, the virtual keys of cell phones become more and more impractical, sometimes it takes multiple clicks of the virtual keys to open a software to enter multiple folders and activate the corresponding function, even for a simple function Like telephoning, the touchscreen is to be activated before dialing and calling, the cumbersome operation process worsens the experience of the user and also makes it difficult for people with limited operational skills to quickly complete the required processes.

At the same time, virtual keys cannot perfectly simulate the physical keys being touched. Therefore, in some operations such as playing games, it is difficult to satisfy the user's touch experience. Due to the limited control area of the cell phone and the size limitation, it is difficult to meet the needs of touch control while accommodating the user's demand for physical buttons. Because of this, it has become an urgent problem for those skilled in the art to provide a physical key-based advanced control system with high efficiency and good convenience.

SUMMARY OF THE PRESENT INVENTION In view of the above, the present invention provides a physical key-based advanced control system and method for quick access to a terminal, the system performing data interaction with a terminal through an external physical key and a wireless communication method, in order to implement an extended control of the terminal, this solves the problem of the existing control method that they cannot take into account the demands for the touch control and the physical buttons at the same time.

° BE2020 / 5874 To achieve the above object, the present invention uses the following technical solution: On the one hand, the present invention provides a physical key-based extended control system comprising: a physical key module, a microprocessor, a wireless communication module and a power supply module , wherein the physical key module is electrically connected to the microprocessor, and wherein one end of the wireless communication module is electrically connected to the microprocessor and the other end is communicatively connected to a terminal with a corresponding communication function, and wherein the power supply module is connected to the

Microprocessor is electrically connected.

The physical key module preferably comprises 9 keys which are arranged in a matrix keyboard, the keys each being electrically connected to the microprocessor.

Preferably, the wireless communication module is any of the Bluetooth module, the NFC module, and the WiFi module.

By having any of the above wireless

Communication module is wirelessly connected to the terminal, the data transfer function can be implemented more conveniently during the extended control.

The power supply module is preferably a wireless charging receiver, a wireless charging transmitter being arranged in the terminal, and the wireless charging transmitter transmitting electrical energy to the wireless charging receiver by electromagnetic induction, and the wireless charging receiver being electrically connected to the microprocessor is.

A wireless charging receiver chip with the model number BQ51013 is preferably selected for the wireless charging receiver.

The wireless charging provides power to the advanced control system without arranging an additional power supply, so that the system has a higher degree of integration and is made more practical.

On the other hand, the present invention further provides a method of quick access to a terminal using the above physical key-based extended control system, comprising: establishing a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal; Establishing a communication channel between the extended control system and the terminal; the terminal acquires the mapping relationship database; the extended control system recognizes the input status of the physical key and sends the corresponding physical key identification to the end device; the terminal receives the physical key identifier sent from the extended control system and acquires the corresponding software function identifier from the mapping relationship database;

; ° BE2020 / 5874 the terminal device executes the corresponding function in accordance with the recorded software function identifier.

Preferably, setting up a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal comprises: presetting a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal in accordance with the control habits of the user and setting up the mapping relationship database; and / or defining a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal by the user and setting up the mapping relationship database. and wherein the enhanced control system recognizes the input state of the physical key using an FSM-based key recognition program algorithm and a cyclic scan interrogation algorithm. Using an FSM-based key recognition program algorithm, the CPU utilization rate is reduced and it is determined whether a key is triggered, using the cyclic scan interrogation algorithm, the specific position of the key is determined so as to encode the detected key values and for the encoded key values a data exchange is carried out by a wired or wireless reliable transmission method with a mobile phone client. Preferably, a data transmission channel is established between the extended control system and the terminal, the communication method between the extended control system and the terminal being any of Bluetooth communication, NFC near field communication and WIFI communication. From the above technical solutions it can be seen that, compared to the prior art, the present invention provides an extended control system based on physical keys and a method for quick access to a terminal, the system interacts with the through the wireless communication module End device off, an extended control function is provided by a module of the physical key (also referred to as a real key), the user can press the physical key module to conveniently control the end device and thus implement a corresponding function, provided normal operation of the terminal, the system can directly access the corresponding function on the terminal using the physical buttons outside the terminal in order to take into account the requests for the touch control and the physical buttons at the same time. In the method, using the above extended control system, rapid access to a terminal device is realized, so that part of the functions on the terminal device can be performed by pressing the

* BE2020 / 5874 external physical button can be controlled and realized more quickly to improve the user's control experience.

BRIEF DESCRIPTION OF THE DRAWING In order to explain the technical solution in the embodiments of the present invention or from the prior art more clearly, the figures to be used in the explanation of the embodiment or for the prior art are briefly presented below. Obviously, the figures described below show only a few embodiments of the present invention. Those of ordinary skill in the art can obtain other figures based on the figures provided without creative work. Figure 1 is a schematic diagram showing the construction of a physical key-based enhanced control system according to the present invention. FIG. 2 is a schematic diagram showing the construction of an extended control system using a Bluetooth module in an embodiment of the present invention. FIG. 3 is a schematic diagram showing the construction of an extended control system using an NFC module in an embodiment of the present invention. FIG. 4 shows a schematic flow diagram of a method for fast access to a terminal according to the present invention. FIG. 5 shows a schematic diagram of the state transition in an exemplary embodiment of the present invention.

DETAILED DESCRIPTION In connection with figures in the embodiment of the present invention, the technical solutions in the embodiment of the present invention will be clearly and fully explained below. Obviously, the illustrated embodiments are not all embodiments, but only a part of embodiments of the present invention. All other embodiments obtained by those skilled in the art on the basis of the embodiments in the present invention without creative work are to be considered within the scope of the present invention. On the one hand, the present invention provides an extended control system based on physical keys, see Figure 1, comprising: a physical key module 1, a microprocessor 2, a wireless communication module 3 and a power supply module 4, the physical key module 1 being electrically connected to the microprocessor 2 and wherein one end of the wireless communication module 3 is electrically connected to the microprocessor 2 and the other end is communicatively connected to a terminal 5 having a corresponding communication function, and wherein the power supply module 4 is electrically connected to the microprocessor 2.

° BE2020 / 5874 In particular, the physical key module 1 comprises 9 keys which are arranged in a matrix keyboard, the keys each being electrically connected to the microprocessor. In the present exemplary embodiment, the physical key module 1 is provided with 9 keys which are arranged in a matrix keyboard. The matrix keyboard is connected using an embedded I / O interface, and the key values are obtained through recognition for the keys. Specifically, the wireless communication module 3 is any of the Bluetooth module, the NFC module, and the WiFi module. See Figure 2, when using the Bluetooth module, a Bluetooth mobile phone is selected as the terminal device, using the wireless Bluetooth technology, the key information is transmitted to the host computer using digital coding technology through frequency modulation, and during the transmission process, the ability of the system to withstand the electromagnetic interference and the cross-talk interference to improve the accuracy of the data during the transmission process. The advanced control system communicates with a bluetooth mobile phone through the bluetooth module, the setting of the button content path can be changed by an Android mobile phone client, at the same time the open state of the button is monitored to complete the quick path.

The bluetooth is an open wireless communication mode. Since the amount of wirelessly transmitted data in the system is relatively small, the Bluetooth module and the Bluetooth mobile phone can communicate using a serial interface. The opening and closing status of the keys in the physical key module is recognized by the microprocessor, in order to record the key values, after the data has been processed in the microprocessor, a command is sent through the Bluetooth module via the serial interface.

When debugging the Bluetooth module in the present exemplary embodiment, the Bluetooth working mode is configured by means of the serial Bluetooth communication module and the USB-to-TTL module. The Bluetooth serial communication module has two working modes: a command response working mode and an automatic connection working mode.

When the module is in a command response working mode, an AT command can be executed, the user can send various AT instructions to the module, set control parameters for the module, or issue control commands for the module. When the module enters the command response working mode, the serial communication baud rate, stop bit and parity bit can be set through the serial debugging wizard.

° BE2020 / 5874 When the module is connected to the embedded bluetooth in an android client app, it can enter the auto connection working mode.

Connect the to enter the automatic connection mode.

The mobile phone transmits the bluetooth serial communication via bluetooth and then communicates with the microprocessor via the serial communication.

The mobile phone transmits the data to the Bluetooth serial communication through the Bluetooth, and then communicates with the microprocessor through the serial communication.

In particular, a one-chip microcontroller of the 51 series is used for the microprocessor in the present exemplary embodiment, with a Bluetooth module for the Bluetooth module.

HC-05 / HC-06 series module is used.

See Figure 3, if an NFC (near field communication) module is used, an NFC mobile phone is selected for the device, NFC is an RFID-based wireless short-range high-frequency communication technology, between electronic devices a contactless point-to-point Data transfer allowed.

Since the

Using a unique signal attenuation technology, near field communication has the characteristics of low cost, high bandwidth, and low power consumption compared to RFID.

In the present embodiment, an NFC-to-serial interface module (shortened to NFC module) is embedded directly in the microprocessor, the module communicates using NFC with an NFC mobile phone and exchanges data by sending a serial interface with the NFC -Mobile phone off.

The NFC module is powered using the serial interface of the microprocessor, the serial interface of the NFC module being connected to the serial interface of the microprocessor.

In particular, the NFC module is implemented by the NFC2COM module.

For the

Microprocessor, a 51 series single-chip microcontroller is selected.

When using the WiFi module, an embedded WiFi module is used to implement network access and data transmission.

The embedded WiFi module (ART-WIFI) is an embedded module that is based on a UART interface, complies with the WIFI standards for wireless networks and has a built-in wireless network protocol and

TCP / IP protocol stack is provided.

Compared to universal WiFi modules, the embedded WiFi module has lower power consumption and does not have high demands on CPU performance.

The communication method between the mobile phone and the single-chip microcontroller uses an AP (Access Point) based wireless network to provide wireless

Provide access services, allowing access from other wireless devices and providing data access.

Communication in the network is completed by AP forwarding.

The WIFI network is set to server mode (IP: 192.168.2.1,

'BE2020 / 5874 port number: 8000), at the same time the SSID of the WIFI module is set and DHCP is activated. In particular, a one-chip microcontroller of the series 51 is used for the microprocessor in the present exemplary embodiment, an ESP8266 chip being used for the WiFi module.

The configuration process for the ESP8266 chip is as follows: (1) through USB to TTL, the ESP8266 chip is connected to a computer; the VCC, GND, CH_PD, UTXD and URXD ports of the ESP8266 chip connect to 3.3V, ground, 3.3V, RXD and TXD of the USB to TTL module, respectively; after the connection is completed, an AT instruction is sent to the ESP8266 chip by the serial debugging assistant; (2) the serial debugging assistant is used to set the baud rate for serial communication (default setting to 115200), and a command to reset AT + RST is sent, if the serial debugging assistant now shows the mess of characters, it will be displayed, that the ESP8266 chip is initialized successfully; (3) the AT instructions change the ESP8266 module information, and the instructions are as follows: AT + CWMODE = 2 // ESP8266 is set to AP mode (send) AT + CWSAP = "PBS", "0123456789" , 11,3 // Configure the AP parameters AT + RST // after configuring AT + CWMODE, the following module should restart so that the configuration becomes valid AT + CIPMUX = 1 // activate multiple connection mode AT + CIPSERVER = 1, 8080 // Server start the connection process of the ESP8266 chip with the one-chip microcontroller is as follows: (1) Change the baud rate of ESP8266, and the instructions are as follows: AT + CIOBAUD = 9600 // Set the baud rate of ESP8266 to 9600 AT + RST // restart the module after changing ESP8266 so that the configuration becomes valid after each restart of the ESP8266 chip two AT instructions should be sent again: AT + CIPMUX = 1 // activate multiple connection mode AT + CIPSERVER = 1.8080 // start server (2) Connect the ESP8266 chip to the one-chip micr ocontrollers, in particular as follows: the VCC, GND, CH_PD, UTXD and URXD ports of the ESP8266 chip are each connected to 23.3V, ground, 3.3V, RXD of the 51-chip microcontroller and TXD of the 51-one-chip microcontroller, the ESP8266 chip and the one-chip microcontroller should be grounded together.

In particular, the power supply module is a wireless charging receiver, wherein a wireless charging transmitter is arranged in the terminal, and wherein the wireless charging transmitter transmits electrical energy to the wireless charging receiver by electromagnetic induction, and the wireless charging receiver is electrically connected to the microprocessor is.

A wireless charging receiver chip BQ51013 from TI is preferably selected for the wireless charging receiver. In the present embodiment, the enhanced control system is powered using the cellular phone (namely, the terminal) proprietary reverse wireless charging technology. The mobile phone is used as the transmitting end, with the alternating current of a certain frequency, the primary coil in the mobile phone generates a specific current in the secondary coil of the receiving end (here the non-power module of the extended control system is used as the receiving end) to absorb the energy from the transmitting end to be transmitted to the receiving end so that the power supply is realized. The system described above can also be referred to as PBS (Physical Button System), namely physical key system, provided that normal use by the user is not impaired, a real key is embedded in the mobile phone housing so that the mobile phone according to the specified path can be addressed to achieve quick service. In particular, the extended control system disclosed in the present exemplary embodiment can be implemented using the cell phone housing as a carrier; in particular, a position for the matrix keyboard is provided in the cell phone housing; a development board (namely the microprocessor), the wireless communication module and the wireless charging receiver are embedded in the interior of the cell phone housing . In the embedding development, the key value of each key is coded, after the user has pressed the key, the MCU (namely the microprocessor) sends the coded key value to the mobile phone (namely the terminal) via the wireless communication module, after receiving the key value the mobile phone compares it with the one through the user-set operating path in order to realize quick access. On the other hand, an embodiment of the present invention further provides a method of quick access to a terminal using the above physical key-based extended control system, comprising: S1: establishing a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal; S2: Establishing a data transmission channel between the extended control system and the terminal;

° BE2020 / 5874 S3: the terminal acquires the mapping relationship database; S4: the extended control system recognizes the input status of the physical key and sends the corresponding physical key identification to the end device; S5: the terminal receives the physical key identifier sent by the extended control system and acquires the corresponding software function identifier from the mapping relationship database; S6: the terminal device executes the corresponding function in accordance with the detected software function identifier. Specifically, setting up a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal includes: presetting a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal in accordance with the control habits of the user and setting up the mapping relationship database; and / or defining a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal by the user and setting up the mapping relationship database.

In the present exemplary embodiment, the user on the Android client (namely on the terminal device) uses the user-defined key usage path to cause the keys to complete the required actuations; the user also only needs the linking function for each key at the end of the embedding (namely on the extended control system) in doing so, the embedded chip (namely the microprocessor) of PBS will recognize the key value of the keys in order to encode the key value triggered by the actuation and transmit it to an APP from the mobile phone which performs a link actuation, thus making it transparent for the user is achieved. In particular, the enhanced control system recognizes the input state of the physical key using an FSM-based key recognition program algorithm and a cyclic scan interrogation algorithm.

In the following, the implementation plan that the above two algorithms realize the key state recognition and the determination of the key position is explained in more detail. See Figure 5, the process with the FSM (Finite State Machine) -based key recognition program algorithm to recognize whether the key is pressed is as follows: In Figure 5, state 0 shows a state without keys, state 1 a state with keys and State 2 is a key confirmation state, "1" indicating that the key is not pressed and "0" indicating that the key is pressed.

FSM in Figure 5 indicates: if the input state of the key is “1”, the output is “0”, and the next state is still “0”; if the input state of the key is “0”, the output is

“0” (no treatment to eliminate shaking, it cannot be confirmed whether the key is pressed) and it enters state “1”. After entering the state “1”, it is in the key confirmation state, if the key is pressed before a certain time series and an input of “0” is recognized, it is displayed that the pressing of the key is confirmed and the output “1” and it enters state “2”, otherwise it is considered to be a jitter and it returns to state “0”. After entering state “2”, it waits for the key to be released, now the output is “0”. The button is released, and that is a complete process.

The process of determining the position of the key using the cyclic scan interrogation algorithm is as follows: Determine if a key is pressed: using the embedded I / O output, all row cables are set low, then the state of the column cables is recognized. When a column is at a low level, it is indicated that a key is pressed and the pressed key is one of the keys with which the column at the low level and the row cables cross each other, otherwise no key is pressed. Detecting the specific position of the key: Set the row cables to a low level one by one, after detecting that a row cable is low level, the level state of the respective column cables is detected one by one. When a column is low, the key at the crossover between the column cable and the row cable set to low is the key depressed. Specifically, a data transmission channel is established between the extended control system and the terminal, the communication method between the extended control system and the terminal being any of Bluetooth communication, NFC near field communication and WIF | communication. In particular, the mapping relationship mentioned in the method disclosed by the present exemplary embodiment can comprise three mapping modes, the physical key identifier in a first mapping mode only corresponds to the function of the body of the mobile phone, in a second mapping mode the physical key identifier only corresponds to the function of the application program of the mobile phone, and in a third mapping mode, the physical key identifier simultaneously corresponds to the function of the body of the cell phone and the function of the application program of the cell phone. In particular, other modes can be set in accordance with actual application needs, it is not defined in detail here. The respective exemplary embodiments in the description are explained progressively. In each exemplary embodiment, the difference from another exemplary embodiment is explained as a focus, the same and similar parts of the respective exemplary embodiments

"BE2020 / 5874 see each other. Since the device disclosed in the exemplary embodiment corresponds to the method disclosed in the exemplary embodiment, the device is explained relatively simply, for the corresponding part see the section on the method.

With the above explanation of the disclosed embodiment, those skilled in the art can make or use the present invention. The various modifications of the exemplary embodiments will be apparent to those skilled in the art, and the general principles defined in the description can be implemented in other exemplary embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention is not limited to the above-described embodiments, but the present invention corresponds to the broadest range that is consistent with the disclosed principles and creative points of the present description.

Claims (9)

EXPECTATIONS A physical key-based extended control system characterized in that it comprises a physical key module, a microprocessor, a wireless communication module and a power module, wherein the physical key module is electrically connected to the microprocessor, and wherein one end of the wireless communication module is connected to the microprocessor electrically connected and the other end communicatively connected to a terminal with a corresponding communication function, and wherein the power supply module is electrically connected to the microprocessor. 2. Extended control system based on physical keys according to claim 1, characterized in that the physical key module comprises 9 keys arranged in a matrix keyboard, the keys each being electrically connected to the microprocessor. 3. The physical key-based extended control system of claim 1, characterized in that the wireless communication module is any one of the Bluetooth module, the NFC module and the WiFi module. 4. Extended control system based on physical keys according to claim 1, characterized in that the power supply module is a wireless charging receiver, wherein a wireless charging transmitter is arranged in the terminal, and wherein the wireless charging transmitter supplies the electrical energy by electromagnetic induction the wireless charging receiver transmits, and wherein the wireless charging receiver is electrically connected to the microprocessor. 5. The extended control system based on physical keys according to claim 4, characterized in that a wireless charging receiver chip with the model number BQ51013 is selected for the wireless charging receiver. 6. A method for quick access to a terminal, characterized in that the method comprises an extended control system based on physical keys according to any one of claims 1 to 5, comprising: setting up a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal ; - Establishing a data transmission channel between the extended control system and the terminal; The terminal acquires the mapping relationship database; - the extended control system recognizes the input status of the physical key and sends the corresponding physical key identifier to the terminal; The terminal receives the physical key identifier sent by the extended control system and acquires the corresponding software function identifier from the mapping relationship database; —The end device executes the corresponding function in accordance with the recorded software function identifier. 7. The method for quick access to a terminal according to claim 6, characterized in that the setting up of a mapping relationship database between the physical key identifier of the extended control system and the software function identifier in the terminal comprises: - Presetting a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal in accordance with the control habits of the user and setting up the mapping relationship database; and / or - defining a mapping relationship between the physical key identifier of the extended control system and the software function identifier in the terminal by the user and setting up the mapping relationship database. 8. The method for fast access to a terminal according to claim 6, characterized in that the extended control system recognizes the input state of the physical key using an FSM-based key recognition program algorithm or a cyclic scan query algorithm. 9. The method for fast access to a terminal according to claim 6, characterized in that a data transmission channel is established between the extended control system and the terminal, the communication method between the extended control system and the terminal being any of the Bluetooth communication, the NFC near field communication and the WIFI communication is on.