KR20130038754A - Communication system - Google Patents

Abstract

PURPOSE: A communication system is provided to execute wireless communication by connecting a server to a portable terminal without taking the portable terminal out of a package. CONSTITUTION: A server(100) includes a first BLE(Bluetooth Low Energy) module(120). The first BLE module periodically transmits payload. A portable terminal(200) includes a second BLE module(220). The second BLE module scans an external signal in a scan cycle which is different from a transmission cycle of the first BLE module. When the payload is received through the scan, the second BLE module communicates with the first BLE module. [Reference numerals] (100) Server; (110) Processor; (120) First BLE module; (130) First Wi-Fi module; (140) Memory; (200a) 1 group; (200A,200B,200C,200N) Portable terminal; (200b) 2 group; (220) Second BLE module; (230) Second Wi-Fi module; (240) Electric potential measuring sensor; (270) Battery;

Description

{COMMUNICATION SYSTEM}

The present invention relates to a communication system between a server performing wireless communication and a mobile terminal.

A mobile terminal is a portable electronic device that is portable and has one or more functions of voice and video call function, information input / output function, and data storing function.

As the functions are diversified, the mobile terminal is implemented in the form of a multimedia player having complex functions such as taking a picture or a video, playing a music or a video file, and receiving a game or a broadcast.

Mobile terminals have come to rely on software to implement the complex functions of such multimedia devices, and software upgrades to correct errors or add functions of software are becoming more and more frequent.

For example, many companies release mobile terminals with new or upgraded software several times a year. The mobile terminals are kept in stock until they are shipped packed and sold to customers.

However, there are cases where an update is necessary because a bug is found in the software of the mobile terminal (eg, the OS of the smartphone) while the mobile terminals are kept in stock. In this case, the mobile terminal is manually removed from the package, the AP is turned on, and the updated software is downloaded to the mobile terminal.

One object of the present invention is to provide a communication system capable of performing wireless communication by connecting a server and a mobile terminal without removing the mobile terminal from a package.

Another object of the present invention is to propose a communication system in which a connection time between a server and a mobile terminal can be shortened.

In order to achieve the above object of the present invention, a communication system according to an embodiment of the present invention includes a first Bluetooth Low Energy (BLE) module that is formed to periodically broadcast a payload. A second server configured to scan an external signal at a scan period different from a transmission period of the server and the first BLE module, and when the payload is received through the scan, is connected to the first BLE module to perform communication; It includes a mobile terminal having a BLE module.

According to an example related to the present invention, the second BLE module is configured to scan an external signal for a preset time. The second BLE module may be configured to have a scan period equal to the sum of the scan time of the second BLE module and a time corresponding to a multiple of the transmission period of the first BLE module. The second BLE module may be configured to scan an external signal for a time corresponding to a divisor of a transmission period of the first BLE module.

According to another example related to the present invention, the period from the time when the scan of the second BLE module is finished to the time when the next scan is started may be a time corresponding to a multiple of the transmission period of the first BLE module. .

According to another example related to the present invention, the mobile terminal further includes an application processor (AP) and a micro controller unit (MCU) configured to activate the AP by using the payload. The payload may include a Bluetooth Device ADDRess (BDADDR) of the mobile terminal, a Wi-Fi Access Point (Basic Service Set IDentifier) BSSID of the server, and an Internet Protocol (IP) address of the server. . In addition, the MCU may be configured to activate the AP when the BDADDR corresponds to the BDADDR of the communication module. When the AP is activated, the mobile terminal may be configured to communicate with the server through the Wi-Fi AP BSSID and the IP address in the payload.

According to another example related to the present invention, the first BLE module includes a plurality of BLE devices each having a different broadcasting channel. The plurality of BLE devices may be configured to transmit different payloads.

According to the present invention having the above configuration, the first BLE module of the server periodically transmits the payload, the second BLE module of the mobile terminal to scan the payload in a different scan period than the transmission period of the first BLE module As a result, the connection between the server and the mobile terminal can be made within a shorter time.

Since the MCU activates the AP using the payload and the mobile terminal is connected to the server to perform wireless communication, the MCU can download a specific program to the mobile terminal without removing the mobile terminal from the package. In addition, the connection time can be shortened through the plurality of transmission channels, and more efficient work can be performed by performing different tasks through the plurality of transmission channels.

1 is a conceptual diagram showing a mobile system connected to a server using a payload transmitted from a first BLE module of a server in a communication system according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating an AP startup system for activating an AP of the mobile terminal shown in FIG. 1.
3 to 5 are conceptual views illustrating a process of sensing a payload transmitted from a first BLE module of a server by a second BLE module of a mobile terminal.
6 is a flowchart illustrating a connection process between a server and a mobile terminal shown in FIG. 1;

EMBODIMENT OF THE INVENTION Hereinafter, the communication system which concerns on this invention is demonstrated in detail with reference to drawings.

The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

1 is a communication system 10 according to an embodiment of the present invention, in which a mobile terminal 200 uses a payload 101 transmitted from a first BLE module 120 of a server 100 to transmit a server 100. FIG. 2 is a block diagram illustrating an AP starting system for activating the AP 210 of the mobile terminal 200 shown in FIG. 1.

1 and 2, the communication system 10 includes a server 100 and a mobile terminal 200. For example, the server 100 may be a workstation, a desktop, a notebook, a tablet PC, or the like, which serves as a workstation and a master device. In addition, the mobile terminal 200 may perform a function as a slave device, and may be provided in plurality (200A-N).

The server 100 is configured to request the mobile terminal 200 to connect with the server 100, and the mobile terminal 200 is set to perform wireless communication by being connected to the server 100 in response to the request. The server 100 and the mobile terminal 200 have a protocol for wireless communication. In addition, the server 100 may request that the mobile terminal 200 activate the AP (Application Processor) 210, and the mobile terminal 200 may be configured to activate the AP 210 in response to the request.

The server 100 includes a processor 110 and a first BLE module 120.

The processor 110 is configured to generate a payload 101 to be transmitted to the mobile terminal 200. The first Bluetooth low energy (BLE) module 120 is configured to broadcast the payload 101 to the mobile terminal 200. The first BLE module 120 may include, for example, a BT (Bluetooth) device having a BLE function, and may be implemented as a dongle that can be easily detached as needed.

The server 100 includes a DB (DataBase) 142 capable of pairing the server 100 with the mobile terminal 200 and a memory 140 storing the same. For example, the DB 142 may include a Bluetooth Device ADDRess (BDADDR), a Personal Identification Number (PIN), or the like of the mobile terminal 200. Pairing of the server 100 and the mobile terminal 200 is performed based on an identification code (eg, BDADDR, PIN code, etc.) of the mobile terminal 200.

The BDADDR may include network addresses of devices having a BT (BlueTooth) function, such as the mobile terminal 200. For example, the BDADDR may be configured with a unique number (eg, 48 bits) used to designate a specific device for connection, pairing, or AP 210 activation. In addition, the PIN code may consist of a four-digit personal ID code based on the serial number of the mobile terminal 200 and the version of the OS of the mobile terminal 200 to be downloaded.

The first BLE module 120 is configured to transmit the payload 101 including at least a portion of the DB 142 to the mobile terminal 200. For example, the payload 101 may include a BDADDR of the mobile terminal 200, a Wi-Fi access point (Basic Service Set IDentifier) BSSID of a server, and an Internet Protocol (IP) address of a server.

BLE proposes a new low-power Bluetooth standard by improving the power consumption of the existing Bluetooth while maintaining the stability and security of the advantages of Bluetooth. BLE separates a data channel and a broadcasting channel. The first BLE module 120 is configured to transmit the payload 101 through at least one of 37, 38, and 39, which are transmission channels, by using the feature of the BLE.

The first BLE module 120 is configured to transmit the payload 101 to the mobile terminal 200 via a transmission channel. When the mobile terminal 200 receives the payload 101 and determines that it is valid (if it is determined to be applicable to itself), the mobile terminal 200 activates the AP 210 and is connected to the server 100 to perform wireless communication. .

The mobile terminal 200 has an AP startup system for activating the AP 210. The AP starting system includes an AP 210, a second BLE module 220, a potential measurement sensor 240, a power management integrated circuit (PMIC) 250, and a micro controller unit (260).

AP 210 includes one or more cores (CPUs), memory, display system / controller, multimedia encoding / decoding codec, 2D / 3D accelerator engine, image signal processor (ISP), camera, audio, modem, multiple high speed / low speed serial It can be implemented as a system-on-chip including a parallel connection interface.

The second BLE module 220 is configured to communicate with the server 100 through the first BLE module 120. The second BLE module 220 may be formed of a BT device 221 having a BLE function so as to consume the minimum power as the first BLE module 120. Since the BT device 221 having the BLE function consumes only a portion (eg, 1 to 5 percent) of power consumed by the general BT device, the BT device 221 may communicate with the first BLE module 120 with minimal power.

Inside the mobile terminal 200, a battery 270 for supplying power to the mobile terminal 200 is built in or detachably mounted. The battery 270 is packaged while being embedded or mounted in the mobile terminal 200. The battery 270 is charged with a predetermined level or more of power, and the battery 270 is configured to supply a quiescent current to the AP starting system through the PMIC 250 until the AP 210 is activated. The AP startup system which activates the AP 210 can be maintained for a long time due to the minimum current generated from the battery 270, i.e., the quiescent current.

The mobile terminal 200 processes the payload 101 transmitted from the server 100, and if the payload 101 is valid, activates the MCU 260 configured to activate the AP 210 of the mobile terminal 200. Include. The MCU 260 may be configured as an example of a controller that controls overall operations related to upgrade such as downloading a specific program by communicating with the server 100. The MCU 260 activates the AP 210 when the second BLE module 220 receives the payload 101 from the server 100 in the standby mode and if the payload 101 is valid. And monitors a signal from the server 100 to be connected to the server 100 to perform wireless communication.

The PMIC 250 is configured to control the power supply to the AP 210. For example, when the communication module 250 receives the payload 101 from the server 100, the potential of the battery 270 measured by the potential measuring sensor 240 is compared with a reference value, and using the comparison result Control the power supply to the AP (210).

The PMIC 250 may be configured to apply power to the AP 210 only when the measured potential is greater than or equal to the reference value. For example, the battery 250 maintains a certain level of power above a certain remaining amount. When the power of the battery 270 falls below a reference value due to the mobile terminal 200 being kept in stock for a long time, the power may be cut off while downloading the software from the server 100. When the remaining capacity of the battery 270 is insufficient by comparing the measured potential with a reference value, the PMIC 250 is configured to maintain a blocked state (or a state of supplying a quiescent current) without applying a power supply. Prevents malfunction due to

The second BLE module 220 may be configured to transmit the measured potential to the server 100. The server 100 may separately manage the mobile terminal 200 in which the remaining amount of the battery 270 is insufficient, based on the measured potential of the transmitted mobile terminal 200.

The AP startup system may further include a power switch 290, a low drop out 282, and a switch 281.

The power switch 290 is connected to the PMIC 250 to selectively supply power to the AP 210, and may be implemented as an operation key exposed to the outside of the mobile terminal 200. The LDO 282 is configured to supply power for the operation of the second BLE module 220. In addition, the switch 281 is configured to leave the AP 210 and the second BLE module 220 open before the AP 210 is activated and close after the AP 210 is activated. For example, when the second BLE module 220 receives the valid payload 101 from the first BLE module 120 and the AP 210 is activated, the second Wi-Fi module 230 may execute a server ( The updated OS is transmitted from the 100 to the AP 210.

The server 100 includes a first Wi-Fi module 130, and the mobile terminal 200 includes a second Wi-Fi module 230. The BT device 221 is difficult to receive a large amount of data, the first and second Wi-Fi module 120 after the AP 210 is activated and the server 100 and the mobile terminal 200 is paired. The program stored in the server 100 is transmitted to the mobile terminal 200 through 230. The program can be, for example, an updated OS or a specific application.

Although the above has been described based on one server 100 and the mobile terminal 200 connected thereto, the performing of pairing or downloading of a program may be simultaneously performed on the plurality of mobile terminals 200A-N illustrated in FIG. It can be done sequentially.

Hereinafter, a communication system in which a server and a mobile terminal can be connected within a shorter time will be described in more detail.

3 to 5 are conceptual views illustrating a process in which the second BLE module 220 of the mobile terminal 200 detects the payload 101 transmitted from the first BLE module 120 of the server 100. 3 illustrates a process in which the second BLE module 220 receives the payload 101 transmitted from the first BLE module 120 only in the first and second scans. The fourth scanning process is shown, and FIG. 5 is a conceptual diagram showing that the same process as the fifth scanning process and the first scanning is repeated.

Referring to FIG. 3, the processor 110 of the server 100 generates a payload 101 to be transmitted to the mobile terminal 200, and the first BLE module 120 periodically moves the payload 101. Is made to transmit to the terminal 200. For example, the first BLE module 120 may be configured to transmit the payload 101 every 25 ms as shown.

As described above, the payload 101 may include an identification code of the mobile terminal 200, information for communication with the server 100, and the like. In detail, the processor 110 may include an identification code of the mobile terminals 200A-N stored in the DB 142, for example, a payload containing only the BDADDR of the mobile terminal 200 to activate the AP 210 among the BDADDRs. Generate 101. In addition, when the AP 210 is activated, the payload 101 includes information for connection with the server 100, for example, a Wi-Fi AP BSSID and an IP address so as to communicate with the server 100. May be included.

The second BLE module 220 of the mobile terminal 200 scans an external signal, that is, the payload 101 transmitted from the server 200 at a scan period different from the transmission period of the first BLE module 120. Is formed. The MCU 260 monitors the payload 101 transmitted from the server 100 through the second BLE module 220, and activates the AP 210 if the payload 101 received during the scanning process is valid. And it is connected to the server 100 via the second BLE module 220, the second Wi-Fi module 230 is set to perform wireless communication.

The second BLE module 220 is configured to scan an external signal for a preset time. For example, the second BLE module 220 may be configured to scan an external signal for a time corresponding to a divisor of the transmission period of the first BLE module 120. In this figure, the scan window of the second BLE module 220 is 5ms.

The period from the time when the scan of the second BLE module 220 is finished to the time when the next scan is started may be a time corresponding to a multiple of the transmission period of the first BLE module 120. Referring to this figure, the period may be 2000ms, that is, 2 seconds, which is a multiple of the transmission period (25ms) of the first BLE module 120.

In this figure, since the time when the second BLE module 220 scans the external signal, that is, the scan window is set to 5 ms, the scan period becomes 2005 ms. In other words, the second BLE module 220 scans by adding the scan time (5 ms) of the second BLE module 220 to the time 2000 ms corresponding to a multiple of the transmission period of the first BLE module 120. It can be made to have a period (2005 ms).

As shown, when the scan window of the second BLE module 220, which is made to scan an external signal for 5 ms and the scan period is 2005 ms, is located at ①, the payload transmitted from the first BLE module 120 ( 101 is detected by the second BLE module 220 which starts scanning after 2 seconds. Therefore, the payload 101 transmitted from the first BLE module 120 is received only in the first scan, and the connection time is approximately 2 seconds.

When the scan window is located at ②, the payload 101 transmitted from the first BLE module 120 is not detected in the first scan process after 2 seconds, and the second BLE module starts scanning again after 2 seconds from this. Is detected by 220. Therefore, the payload 101 transmitted from the first BLE module 120 is received in the second scan, and the connection time is approximately 4 seconds.

4 and 5, through the above-described process, when the scan window is located at ③, ④, and ⑤, the second BLE module 220 is configured to display the first BLE module (only after the third, fourth, and fifth scans, respectively). The payload 101 transmitted from 120 is received. The time taken for the second BLE module 220 to detect the payload 101 is approximately 6, 8, and 10 seconds, respectively.

Referring to FIG. 5, the payload 101 is detected by the scan window located at ① again after 12 seconds. That is, regardless of whether the scan window is located at ①, ②, ③, ④, or ⑤, the second BLE module 220 must always be removed from the first BLE module 120 of the server 100 within 10 seconds. The payload 101 is transmitted.

According to the present invention having the above configuration, the first BLE module 120 of the server 100 periodically transmits the payload 101, the second BLE module 220 of the mobile terminal 200 is a first The payload 101 is formed to be scanned at a scan period different from that of the BLE module 120, so that the connection between the server 100 and the mobile terminal 200 can be made within a shorter time. In addition, since the connection time between the server 100 and the mobile terminal 200 can be shortened by regular and staggered syncronization, power consumption of the mobile terminal 100 can be minimized.

6 is a flowchart illustrating a process of connecting a server and a mobile terminal shown in FIG. 1.

Referring to FIG. 6, the MCU 260 activates the AP 210 when the BDADDR included in the payload 101 corresponds to the BDADDR of the second BLE module 220. If none of the BDADDRs included in the payload 101 corresponds to the BDADDR of the second BLE module 220, the server 100 may be reported to the server 100 and may be set to remain in the standby mode.

When the AP 210 is activated, the second BLE module 220 may be configured to transmit a response signal indicating that the payload 101 has been received to the server 100. The response signal may be formed in a form for obtaining additional information by sending a scan request to the broadcaster, that is, the server 100 after receiving the payload 101. In addition, the server 100 may be configured to deliver a response signal to the scan request, that is, a scan response (for example, 0 or a null value).

Next, the mobile terminal 200 is prepared to communicate with the server 100 by the second Wi-Fi module 230 is activated. For example, the mobile terminal 200 is connected to the server 101 through the Wi-Fi AP BSSID and the IP address of the server 101 included in the payload 101. The connection method may be an infrastructure mode through an access point (AP) of the server 100 or an ad-hoc mode which is a direct connection between the first and second Wi-Fi modules 130 and 230.

When the server 100 and the mobile terminal 200 are paired, programs stored in the server 100 are transmitted to the mobile terminal 200 through the first and second Wi-Fi modules 130 and 230. The program can be, for example, an updated OS or a specific application. When the download of the program is completed, the second BLE module 220 may be configured to report that the download is completed to the server 100.

The first BLE module 120 may include a plurality of BLE devices having different transmission channels. The plurality of BLE devices are configured to transmit the payload 101 through at least one of 37, 38, and 39, which are transmission channels of the BLE, respectively.

The plurality of BLE devices may be configured to transmit the same payload 101 to each other. In this case, there is an advantage in that the transmission range of the payload 101 can be expanded to activate the AP 210 of more mobile terminals 200A-N for the same time.

The plurality of BLE devices may be configured to transmit different payloads 101, respectively. For example, at least one of the payloads 101 and the identification code of the mobile terminals 200A-N or the information for connection with the server 100 is configured differently from the other payloads 101. Can be.

According to the above configuration, since the MCU 260 activates the AP 210 using the payload 101 and the mobile terminal 200 is connected to the server 100 to perform wireless communication, the mobile terminal ( A specific program can be downloaded to the mobile terminal 200 without taking out 200 from the package. In addition, the connection time can be shortened through the plurality of transmission channels, and more efficient work can be performed by performing different tasks through the plurality of transmission channels.

The above-described communication system is not limited to the configuration and method of the embodiments described above, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

Claims (11)

A server having a first Bluetooth Low Energy (BLE) module that is configured to periodically broadcast a payload; And
The second BLE module is configured to scan an external signal at a scan period different from the transmission period of the first BLE module, and is connected to the first BLE module to perform communication when the payload is received through the scan. Communication system comprising a mobile terminal having a. The method of claim 1,
The second BLE module is configured to scan an external signal for a predetermined time. The method of claim 2,
And the second BLE module has a scan period equal to a time corresponding to a multiple of a transmission period of the first BLE module plus a scan time of the second BLE module. The method of claim 3, wherein
The second BLE module is configured to scan an external signal for a time corresponding to a divisor of the transmission period of the first BLE module. The method of claim 1,
And a period from the time when the scan of the second BLE module is completed to the time when the next scan is started is a time corresponding to a multiple of the transmission period of the first BLE module. The method of claim 1,
The mobile terminal includes:
An application processor (AP); And
And a micro controller unit (MCU) configured to activate the AP using the payload. The method according to claim 6,
The payload is
A Bluetooth Device ADDRess (BDADDR) of the mobile terminal;
Wi-Fi Access Point (BS) Basic Service Set IDentifier (BSSID) of the server; And
And an Internet Protocol (IP) Address of the server. 8. The method of claim 7,
The MCU is configured to activate the AP when the BDADDR corresponds to the BDADDR of the communication module. The method of claim 8,
When the AP is activated, the mobile terminal is configured to communicate with the server through the Wi-Fi AP BSSID and the IP address in the payload. The method of claim 1,
The first BLE module includes a plurality of BLE devices each having a different transmission channel (broadcasting channel). The method of claim 10,
And the plurality of BLE devices are configured to transmit different payloads.

Images