JP6606922B2 - COMMUNICATION DEVICE, CLOCK, AND COMMUNICATION METHOD - Google Patents

Description

  The present invention relates to a communication device, a timepiece, and a communication method.

Conventionally, two-way short-range wireless communication is performed by Bluetooth (registered trademark).
For example, Patent Document 1 discloses a technology for exchanging information necessary for Bluetooth pairing by using a non-contact IC (Integrated Circuit) by NFC (Near Field Communication) in order to start bidirectional communication by Bluetooth. Is disclosed.

  In addition, recently, a user can be provided with a convenient function (such as notifying the watch of incoming calls or emails) by connecting the watch and smartphone via Bluetooth and linking both devices. ing.

JP 2009-60526 A

  By the way, in order to communicate with a specific partner on a one-to-one basis via Bluetooth, it is necessary to know a BD (Bluetooth Device) address that uniquely identifies the partner. For example, a mobile terminal such as a smartphone needs to specify a BD address of a connection destination clock before connection.

  In this case, it is conceivable that the watch intermittently broadcasts a packet including the BD address of its own device, but the mobile terminal cannot receive the packet due to the influence of the communication environment (for example, distance between devices or external noise). There is. On the other hand, even if the mobile terminal can receive a packet, if a plurality of packets from other clocks are received at the same time, the user may make a mistake in selecting a connection destination clock.

  Furthermore, since the technique of Patent Document 1 exchanges information such as a BD address using a non-contact IC, there is a difficulty in mounting space for the non-contact IC for a wearable small device such as a watch.

  For this reason, it is desired to easily and reliably connect to a connection target device without restrictions on mounting space and without depending on a communication environment or user operation.

  Therefore, the present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a communication device and the like that can easily and reliably connect to a connection target device.

In order to achieve the above object, the communication device of the present invention provides:
Display control means for controlling the display of address data for uniquely identifying its own device by changing a combination of numbers indicated by a plurality of pointers over time;
Communication control means for controlling connection with another device that has decoded the address data controlled by the display control means;
It is provided with.

  According to the present invention, it is possible to easily and reliably connect to a device to be connected.

It is a figure which shows the external appearance of the portable terminal and watch which concern on embodiment. It is a figure which shows the external appearance of the back surface of the portable terminal which concerns on embodiment. It is a block diagram which shows the structure of the timepiece which concerns on embodiment. (A)-(l) is the figure which showed the example of a display of the address data of a timepiece in order. (A)-(f) is the figure which showed the example of a display of a pairing key in order. It is a block diagram which shows the structure of the portable terminal which concerns on embodiment. It is a figure which shows the example of the conversion table. It is a figure which shows the example of the conversion table. It is a figure which shows the flowchart of a display control process of a timepiece. It is a figure which shows the flowchart of a pairing process of a portable terminal. It is a sequence diagram which concerns on pairing between a portable terminal and a timepiece.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a view showing the appearance of a portable terminal and a watch according to an embodiment of the present invention.

  The mobile terminal 10 is a smartphone capable of short-range wireless communication using Bluetooth. The portable terminal 10 includes a liquid crystal display unit 11 and an operation unit 12 that is a button for performing a determination input.

  On the other hand, the watch 20 is an analog wristwatch capable of short-range wireless communication by Bluetooth. The timepiece 20 has a dial 21 (first hand) 22, a second hand (second hand) 23, an hour hand (third hand) 24 on a dial 21, and a crown 25 used for manual time setting. And a push-type button 26 for mode switching. The watch 20 includes a normal mode for displaying time and a pairing mode for pairing (mutual device authentication) with a communication partner via Bluetooth. The mode switching method is arbitrary. For example, the user may press the button 26 for a predetermined time (for example, 2 seconds) to switch from the normal mode to the pairing mode.

  The portable terminal 10 and the watch 20 provide a highly convenient function to the user by performing bidirectional data communication after pairing. For example, the mobile terminal 10 notifies the clock 20 by data communication that an incoming call or mail has been received, or the clock 20 receives accurate time information from the mobile terminal 10 and corrects the time.

  Prior to this data communication, the mobile terminal 10 acquires an address (also referred to as a BD address or a device address) that uniquely identifies the timepiece 20 as a connection destination and connects to the timepiece 20. After the connection, the mobile terminal 10 acquires a pairing key from the clock 20 and performs pairing with the clock 20. Thereafter, data communication becomes possible.

  In the present invention, these addresses and pairing keys are displayed using a plurality of hands of the watch 20, and the mobile terminal 10 captures the dial 21 with the rear camera 13 shown in FIG. Read and get. Details of the display and reading will be described later. The pairing key is an authentication number (PIN code) necessary for device authentication. The portable terminal 10 and the watch 20 communicate with each other by BLE (Bluetooth Low Energy), which is a Bluetooth standard established for the purpose of low power consumption.

The outlines of the mobile terminal 10 and the timepiece 20 have been described above, but specific configurations will be described in order below. FIG. 3 is a block diagram showing the configuration of the timepiece 20.
As shown in the figure, the timepiece 20 includes a plurality of hands (minute hand 22, second hand 23, hour hand 24), crown 25, button 26, speaker 27, and communication device 200. Since the crown 25 and the button 26 have been described above, description thereof will be omitted.

  The minute hand (first pointer) 22 is a long hand and is a pointer indicating the minute on the dial 21. The second hand (second pointer) 23 is a pointer indicating the second of time on the dial 21. The hour hand (third pointer) 24 is a short hand and is a pointer indicating the hour on the dial 21. These plural guidelines can be controlled independently. That is, a stepping motor as a driving source and a train wheel composed of a plurality of gears are configured independently for each pointer so that power is transmitted to each pointer independently.

The speaker 27 is an audio output unit that outputs audio externally. For example, the speaker 27 notifies a predetermined beep sound when the mode is switched or when pairing is completed.
The communication device 200 includes a control unit 210 and a short-range wireless communication unit 216.
The communication device 200 is a communication module that performs display control of the address and pairing key and connection control with the mobile terminal 10. In this embodiment, a case where the communication device 200 is built in and built in the timepiece 20 will be described as an example.

  The control unit 210 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The control unit 210 implements the functions of each unit (the display control unit 211 and the communication control unit 212) by executing a program stored in the ROM (for example, a program related to a display control process described later).

  The short-range wireless communication unit 216 includes a circuit block (BLE LSI (Large Scale Integration)) for short-range wireless communication based on Bluetooth, an antenna, and the like. The LSI constituting the short-range wireless communication unit 216 supplies a pairing key to the control unit 210 in response to a pairing key acquisition request from the control unit 210.

Next, functions of the control unit 210 will be described.
The control unit 210 includes a display control unit 211 and a communication control unit 212 as functions.

  The display control unit 211 controls the display of address data that uniquely identifies the device itself by changing a combination of numbers indicated by a plurality of hands over time. Specifically, the display control unit 211 uniquely identifies the device itself by changing a combination of numbers indicated by a plurality of hands (minute hand 22, second hand 23, hour hand 24) on the dial 21 over time. The address is displayed on the dial 21. The address is a combination of numbers and characters (particularly alphabets) displayed on the dial 21 based on the address data. Since the address data and the address are substantially synonymous, the following description will be unified with “address data”.

  Of the plurality of hands, the display control unit 211 sets the minute hand 22 to a predetermined numerical position indicating that address data is being displayed, the second hand 23 to a numerical position indicating a digit of the address data, and the hour hand 24 to address data. Control each to the position of the area to which the value of is assigned. That is, the minute hand 22 indicates whether address data is being displayed or a pairing key is being displayed, the second hand 23 indicates the digit of the address data, and the hour hand 24 indicates the value of the address data.

  Here, a display example of address data will be described with reference to FIG. The address data is a 12-digit hexadecimal number, and as an example, it is assumed that 0x: B37EA53FB26D. The initial 0x indicates a hexadecimal number. Further, as indicated by a dotted line in the figure, each hexadecimal value (0 to F indicated by italics) is assigned in ascending order to each area obtained by dividing the circumference of the dial 21 into 16 equal parts. In other words, each hexadecimal value is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 16 equal parts. Note that each dotted line area and each hexadecimal value shown in FIG. 4 are displayed for convenience of explanation, and need not be displayed on the actual dial 21.

  The display control unit 211 first fixes the minute hand 22 to a predetermined number (12:00) indicating that address data is being displayed. In this state, the display control unit 211 changes the second hand 23 and the hour hand 24 over time as shown in (a) to (l). That is, the position of the second hand 23 is changed in ascending order (from 1 to 12 digits) to the position of the number indicating the digit of the address data, and at the same time, the position of the hour hand 24 is changed to the area assigned with the digit value of the address data. Let

  Specifically, the display control unit 211 changes the hour hand 24 to an area to which the one-digit value “B” of the address data is assigned when the second hand 23 points to “1” (see FIG. 4A). While the second hand 23 moves 30 degrees from “1” to “2”, the hour hand 24 is changed to an area to which the value “3” of the second digit of the address data is assigned (see FIG. 4B). While the second hand 23 moves 30 degrees from “2” to “3”, the hour hand 24 is changed to an area to which the third digit value “7” of the address data is assigned (see FIG. 4C).

  In this manner, the display control unit 211 adjusts the digit according to the position of the second hand 23 (1 → 2 → 3 → 4 → 5 → 6 → 7 → 8 → 9 → 10 → 11 → 12). The value according to the position of 24 is changed (B → 3 → 7 → E → A → 5 → 3 → F → B → 2 → 6 → D) to display 12-digit hexadecimal address data on the dial 21. (See FIGS. 4 (a) to (l)).

  It should be noted that the second hand 23 may be pointed in order by 30 degrees in the clockwise direction, but the hour hand 24 must be rotated to the address data value area while the second hand 23 advances 30 degrees. For this reason, the display control unit 211 controls the speed of the second hand 23 and the hour hand 24 so that the hour hand 24 is in the digit value area when the second hand 23 points to the digit of the digit. For example, the display control unit 211 controls the speed so as to match the display timing of the address data digits and values by slowing down the second hand 23 while speeding up the hour hand 24.

  Now, a display example of a pairing key for pairing will be described with reference to FIG. The display of the pairing key is performed after establishing a connection with the mobile terminal 10 which has read and read the address data by the address data display of FIGS. The pairing key is a 6-digit decimal number, and is 738025 as an example. Further, as indicated by dotted lines in the figure, decimal values (0 to 9 shown in italics) are assigned in ascending order to the respective areas obtained by dividing the circumference of the dial 21 into 10 equal parts. In other words, each decimal value is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 10 equal parts. It should be noted that each dotted line area and each decimal value shown in FIG. 5 are displayed for convenience of explanation, and need not be displayed on the actual dial 21.

  The display control unit 211 first fixes the minute hand 22 to a number (6 o'clock) different from a predetermined number indicating that the pairing key is being displayed. In this state, the display control unit 211 changes the second hand 23 and the hour hand 24 over time as shown in (a) to (f). That is, the position of the second hand 23 is changed in ascending order (1 to 6 digits) to the position of the number indicating the digit of the pairing key, and at the same time, the position of the hour hand 24 is assigned to the value of the digit of the pairing key To change.

  Specifically, the display control unit 211 changes the hour hand 24 to an area to which the first digit value “7” of the pairing key is assigned when the second hand 23 points to “1” (FIG. 5A). (Refer to FIG. 5B) While the second hand 23 moves 30 degrees from “1” to “2”, the hour hand 24 is changed to an area to which the value “3” of the second digit of the pairing key is assigned. Subsequently, while the second hand 23 moves 30 degrees from “2” to “3”, the hour hand 24 is changed to an area to which the value “8” of the third digit of the pairing key is assigned (see FIG. 5C). ).

  In this manner, the display control unit 211 changes the value according to the position of the hour hand 24 (7 → 3 →) in accordance with the change of the digit according to the position of the second hand 23 (1 → 2 → 3 → 4 → 5 → 6). 8 → 0 → 2 → 5), and a 6-digit decimal pairing key is displayed on the dial 21 (see FIGS. 5A to 5F).

  Now, returning to FIG. 3, the communication control unit 212 controls connection with the mobile terminal 10 that has decoded the address data display-controlled by the display control unit 211. The portable terminal 10 reads and acquires an address (a combination of numbers and characters indicated by address data) by photographing the dial 21. For this reason, it can be said that the communication control unit 212 controls the connection with the mobile terminal 10 acquired by reading the address data displayed by the display control unit 211. The communication control unit 212 includes a connection request receiving unit 213, a connection establishing unit 214, and a pairing unit 215.

The connection request receiving unit 213 receives a connection request transmitted from the mobile terminal 10 that has decoded the address data.
The connection establishment unit 214 establishes a connection with the mobile terminal 10 in response to the connection request received by the connection request reception unit 213.
The pairing unit 215 performs pairing with the mobile terminal 10 that has acquired the pairing key. Specifically, the pairing unit 215 performs mutual authentication with the mobile terminal 10 using a common pairing key to perform pairing.

  The configuration of the timepiece 20 has been described above with reference to FIGS. Below, the structure of the portable terminal 10 is demonstrated.

  As illustrated in FIG. 6, the mobile terminal 10 includes a display unit 11, an operation unit 12, a camera 13, a storage unit 14, a control unit 15, a short-range wireless communication unit 16, a wireless communication unit 17, and a speaker 18.

The display unit 11 is a terminal screen configured by, for example, an LCD (Liquid Crystal Display), an EL (Electro Luminescence) display, or the like. In the pairing mode, the display unit 22 displays a dial 21 photographed by the user with the camera 13.
The operation unit 12 is arranged on the upper surface of the display unit 22 and is a touch panel used for inputting user operation contents, a button for determining input, or the like.
The camera 13 is an imaging module that includes an imaging device such as a CCD (Charge Coupled Device) or CMOS (Complementary Metal Oxide Semiconductor) and an optical system such as an autofocus lens.

  The storage unit 14 is an internal storage of several gigabytes in the smartphone, and includes a built-in flash memory. The storage unit 14 stores various application programs of smartphones, photographed photos / moving images (particularly, moving images obtained by photographing the dial 21), and the like.

  As various applications, in particular, an application program for decrypting and reading the address data and the pairing key and pairing with the watch 20 is stored. This program is stored in the storage unit 14 when a user installs an application for pairing in the mobile terminal 10 in advance. By installing this application, the storage unit 14 stores the conversion tables 1 and 2 shown in FIGS. 7 and 8 that are necessary for analyzing the captured moving image. These conversion tables 1 and 2 will be described later. This application is not limited to pairing with the watch 20, but is a general-purpose application that can be paired as long as the watch displays address data using a plurality of hands.

  The control unit 15 includes a CPU, a RAM, and the like. The control unit 15 executes the program stored in the storage unit 14 (for example, a program related to pairing processing to be described later), thereby enabling the functions of the respective units (the imaging unit 151, the address acquisition unit 152, and the communication control unit 153). Realize.

The short-range wireless communication unit 16 includes a circuit block (BLE LSI) for short-range wireless communication based on Bluetooth, an antenna, and the like.
The wireless communication unit 17 includes a circuit block and an antenna for wireless communication based on WiFi (Wireless Fidelity) or 4G (4th Generation). The communication control unit 153 can connect to the Internet via the wireless communication unit 17.
The speaker 18 is an audio output unit that outputs audio externally.

Next, functions of the control unit 15 will be described.
The control unit 15 includes a photographing unit 151, an address acquisition unit 152, and a communication control unit 153 as functions.

  The photographing unit 151 photographs the dial 21 of the clock 20 by controlling the camera 13. Specifically, when the user points the camera 13 toward the dial 21, the shooting unit 151 automatically adjusts the focus and outputs a live image of the dial 21 being shot to the display unit 11. At this time, if the entire dial 21 is not shown in the live image being photographed or if the dial 21 is shifted from the center of the display unit 11, the speaker 18 displays the entire dial 21 on the display screen. “Please make sure that the dial 21 is displayed in the center of the display screen.”

  Next, the address acquisition unit 152 decodes and acquires the address data that uniquely identifies the clock 20 based on the temporal change of the combination of numbers indicated by the plurality of hands on the dial 21 photographed by the photographing unit 151. . The address acquisition unit 152 acquires a pairing key for pairing with the watch 20 in the same manner.

  Now, reading of address data and a pairing key performed by the address acquisition unit 152 will be described with reference to the conversion table 1 of FIG. 7 and the conversion table 2 of FIG. These address data and the pairing key are acquired by analyzing a moving image shot by the user. The shooting time of the movie is a time that has a sufficient margin in the time from the start to the end of the address data display and the pairing key display.

  For example, in the case of address data display, the second hand 23 may go around the dial 21, that is, all 12 digits that are digits of the address data may be set to a time with a margin in the time when the second hand 23 has finished pointing. On the other hand, in the case of the pairing key display, it is preferable that the second hand 23 circulates the dial 21 halfway, that is, all six digits as the pairing key digits are set to a time with a margin in the time when the second hand 23 has finished pointing.

  First, in the case of reading the address data displayed on the dial 21, the address acquisition unit 152 indicates that the number indicated by the minute hand 22 is “12” for the captured moving image (the moving image in which FIGS. 4A to 4L are captured). The angle pointed by the hour hand 24 at the timing when the second hand 23 points to the digit of the digit (clockwise angle with the 12 o'clock direction being 0 degree) is measured. Then, the address acquisition unit 152 converts the measured angle using the conversion table 1 and acquires a hexadecimal value.

  For example, in FIG. 4A, the address acquisition unit 152 uses the conversion table 1 because the angle indicated by the hour hand 24 measured at the timing when the second hand 23 points to the single digit “1” is 247.5 ° to 270 °. The hexadecimal value “B” is acquired. This process is repeated for each digit, and the address data is acquired by filling all the 12-digit numerical values.

  On the other hand, in the case of reading the pairing key displayed on the dial 21, the address acquisition unit 152 indicates that the number indicated by the minute hand 22 is "" for the captured moving image (the moving image in which FIGS. 5A to 5F are captured). The angle pointed by the hour hand 24 is measured at the timing when the second hand 23 points to the digit of the digit while confirming whether it is fixed at “6”. Then, the address acquisition unit 152 converts the measured angle using the conversion table 2 and acquires a decimal value.

  For example, in FIG. 5A, the address acquisition unit 152 indicates that the angle indicated by the hour hand 24 measured at the timing when the second hand 23 indicates the single digit “1” is 252 ° to 288 °. The value “7” is acquired. This process is repeated for each digit, and a 6-digit numerical value is filled to obtain a pairing key.

  As described above, the address acquisition unit 152 performs the angle conversion indicated by the hour hand 24 using the conversion tables 1 and 2, reads the value assigned to the area, and acquires the address data and the pairing key.

Now, returning to FIG. 6, the communication control unit 153 includes a connection request transmission unit 154, a connection establishment unit 155, and a pairing unit 156.
When the address acquisition unit 152 acquires address data, the connection request transmission unit 154 transmits a connection request to the clock 20 of the address data.
The connection establishment unit 155 establishes a connection with the clock 20 that has received the connection request.
The pairing unit 156 performs mutual authentication with the clock 20 using the common pairing key acquired by the address acquisition unit 152 and performs pairing with the clock 20. After pairing, the mobile terminal 10 performs data communication with the watch 20.

The configuration of the mobile terminal 10 has been described above with reference to FIGS. Hereinafter, the display control process of the timepiece 20 will be described with reference to FIG.
This display control process is started when the timepiece 20 is switched from the normal mode to the pairing mode.

  First, the display control unit 211 fixes the minute hand 22 to a predetermined number (step S11). Specifically, the display control unit 211 fixes the minute hand 22 at the position “12” indicating that the address data is being displayed (see FIG. 4A).

  Next, the display control unit 211 performs address data display using the hour hand 24 and the second hand 23 (step S12). Specifically, the display control unit 211 assigns the hour hand 24 to the one-digit value “B” of the address data when the second hand 23 indicates “1” while the minute hand 22 is fixed at the “12” position. The area is changed to the specified area (see FIG. 4A).

  Next, the communication control unit 212 transmits an advertisement (step S13). According to the Bluetooth communication standard, a connection request is transmitted in response to receiving (scanning) an advertisement. That is, in this embodiment, the mobile terminal 10 transmits a connection request in response to receiving an advertisement after acquiring address data by moving image analysis. For this reason, the communication control unit 212 of the timepiece 20 transmits advertisements intermittently (for example, at intervals of 0.3 seconds).

  Next, the connection establishment unit 214 determines whether or not a connection with the mobile terminal 10 has been established (step S14). Specifically, the connection establishment unit 214 receives the connection request from the portable terminal 10 and establishes the connection, and then determines whether or not the connection establishment completion is notified from the BLE LSI constituting the short-range wireless communication unit 216. The above determination is made.

  Here, when the connection with the portable terminal 10 has not been established (step S14; No), it is determined whether or not the specified time has elapsed (step S15). This specified time is set to be longer than the shooting time of a moving image (moving image of the dial 21 during address data display) by the mobile terminal 10. This is because the mobile terminal 10 makes a connection request after acquiring address data by moving image analysis after moving image shooting, and therefore cannot establish a connection if the specified time is shorter than the shooting time. For this reason, the specified time is at least the time for which the second hand 23 goes around the dial 21, that is, the time for which the second hand 23 finishes pointing all 12-digit address data.

  Until this specified time elapses (step S15; No), the address data display by the hour hand 24 and the second hand 23 is performed while intermittently transmitting the advertisement and monitoring whether the connection with the portable terminal 10 has been established. Continue (loop of steps S12 to 15).

  Here, after the second hand 23 has pointed to all the 12-digit address data (see FIGS. 4A to 4L), the connection with the mobile terminal 10 is not established (step S14; No), and the specified time has elapsed. When it does (step S15; Yes), the communication control part 212 stops the transmission of an advisor (step S16). At the same time, the display control unit 211 stops address data display (step S17). The processes in step S16 and step S17 are performed when the moving image analysis fails due to reasons such as moving image blurring and the mobile terminal 10 cannot acquire address data and the specified time has elapsed.

  Then, the display control unit 211 restores the normal time display (step S18). Specifically, the display control unit 211 switches from the pairing mode to the normal mode, reads the time information from an RTC (Real Time Clock) that holds accurate time information in real time, and returns to the normal time display. Thereafter, the display control process is terminated (in this case, termination due to a connection error).

  On the other hand, after the second hand 23 has pointed out all the 12-digit address data (see FIGS. 4A to 4), the connection with the portable terminal 10 is established before the specified time elapses (step S14; Yes). The display control unit 211 transitions to the pairing key display. Prior to displaying the pairing key, the control unit 210 makes a pairing key acquisition request to the short-range wireless communication unit 216 and acquires the pairing key from the short-range wireless communication unit 216.

  When transitioning to the pairing key display, the display control unit 211 fixes the minute hand 22 to a number different from a predetermined number (step S19), and displays the pairing key with the hour hand 24 and the second hand 23 (step S20).

  Specifically, the display control unit 211 fixes the hour hand 24 when the second hand 23 indicates “1” after fixing the minute hand 22 at the “6” position indicating that the pairing key is being displayed. The area is changed to an area to which the one-digit value “7” of the ring key is assigned (see FIG. 5A).

  Next, the pairing unit 215 determines whether pairing with the mobile terminal 10 has been completed (step S21). Specifically, the pairing unit 215 makes the above determination based on whether or not mutual authentication using a common pairing key has been performed, triggered by the mobile terminal 10 acquiring a pairing key.

  When the pairing has not been completed (step S21; No), the display control unit 211 determines whether the specified time has elapsed (step S22). When the specified time has not elapsed (step S22; No), the display control unit 211 continues to display the pairing key with the hour hand 24 and the second hand 23 until the specified time elapses (FIG. 5A). ) To (f)), it is determined whether or not pairing with the mobile terminal 10 is completed (a loop of steps S20 to S22).

  The specified time in step S22 is longer than the shooting time of the moving image (moving image of the dial 21 displaying the pairing key) by the mobile terminal 10. Thereby, the specified time is at least the time for which the second hand 23 makes a half turn on the dial 21, that is, the time for which the second hand 23 finishes pointing all the 6-digit pairing keys.

  Here, after the second hand 23 has pointed out all the 6-digit pairing keys (see FIGS. 5A to 5F), the pairing with the portable terminal 10 is not completed (step S21; No), and the specified time Has elapsed (step S22; Yes), the display control unit 211 stops the pairing key display (step S23). That is, as in the case of address data acquisition, if the mobile terminal 10 cannot acquire the pairing key and the specified time has elapsed because of a moving image, the display control unit 211 stops displaying the pairing key To do.

  Then, the display control unit 211 returns the dial 21 to the normal time display (step S18), and ends the display control process (in this case, the process ends due to a pairing error).

  On the other hand, after the second hand 23 finishes pointing all the 6-digit pairing keys (see FIGS. 5A to 5F), the pairing with the portable terminal 10 is completed before the specified time elapses (step S21; Yes), the display control process ends (in this case, normal termination due to successful pairing).

  The display control processing by the clock 20 has been described above. Next, the pairing process by the portable terminal 10 will be described with reference to FIG. This pairing process is started when the user of the mobile terminal 10 activates an application for pairing and sets the mobile terminal 10 to the pairing mode.

  First, the photographing unit 151 instructs the camera 13 to photograph the dial 21 of the timepiece 20 (step S31). Specifically, the photographing unit 151 may “display the entire dial 21 on the display screen” so that the entire dial 21 of the clock 20 is displayed on the display screen of the display unit 11. Instruct the user by voice or text. At the same time, the image capturing unit 151 instructs the user by voice or text to continuously capture a moving image for the time necessary to acquire the address data.

  Next, the address acquisition unit 152 determines whether or not address data has been acquired (step S32). Specifically, the address acquisition unit 152 uses the conversion table 1 in FIG. 7 in the manner described above, analyzes the moving image obtained by shooting in step S31, and tries to read the address data.

  Here, when the address data cannot be obtained (step S32; No), that is, when the address data cannot be read due to the face 21 of the captured moving image being shaken, the process returns to step S31, and the photographing unit 151 The camera 13 is again instructed to photograph the dial 21. Since the clock 20 continues displaying the address data until the specified time elapses, by increasing the specified time (for example, by setting the specified time to be twice the moving image shooting time), the user again displays the dial. It is possible to retry the acquisition of the address data by taking 21 images.

  On the other hand, when the address acquisition unit 152 acquires address data (step S32; Yes), the communication control unit 153 performs connection processing with the clock 20 of the acquired address data (step S33). Specifically, after receiving the advertisement transmitted from the clock 20, the connection request transmission unit 154 transmits a connection request to the clock 20, and the connection establishment unit 155 establishes a connection with the clock 20.

  After establishing connection with the watch 20, the photographing unit 151 instructs the camera 13 to photograph the dial 21 of the watch 20 (step S34). The photographing unit 151 instructs to shoot a moving image continuously for a time necessary to acquire the pairing key by voice or text.

  Next, the address acquisition unit 152 determines whether or not a pairing key has been acquired (step S35). Specifically, the address acquisition unit 152 attempts to read the pairing key by analyzing the moving image obtained by the shooting in step S34 using the conversion table 2 of FIG. 8 in the manner described above.

If the pairing key could not be acquired (step S35; No), the process returns to step S34, and the imaging unit 151 prompts the user to retry.
On the other hand, when the address acquisition unit 152 acquires the pairing key (step S35; Yes), the pairing unit 156 performs pairing with the watch 20 using the acquired pairing key (step S36). Specifically, the pairing unit 156 performs pairing by performing mutual authentication with the watch 20 using a common pairing key. Thereafter, the pairing process is terminated.

  Next, a pairing flow between the mobile terminal 10 and the timepiece 20 will be described with reference to FIG. As a premise, it is assumed that the mobile terminal 10 and the watch 20 are in the pairing mode. Further, it is assumed that the clock 20 transmits an advertisement after receiving an address until a connection request is received.

  First, the display control unit 211 of the timepiece 20 displays address data on the dial 21 (see FIGS. 4A to 4L). The photographing unit 151 of the portable terminal 10 photographs the dial 21. Next, the address acquisition unit 152 of the mobile terminal 10 reads and acquires the address data displayed on the dial 21. Next, the connection request transmission unit 154 of the mobile terminal 10 transmits a connection request to the clock 20 of the acquired address data, and the connection establishment unit 155 establishes a connection with the clock 20.

  After establishing the connection, the watch 20 displays a pairing key on the dial 21 (see FIGS. 5A to 5F). The photographing unit 151 of the portable terminal 10 photographs the dial 21. Next, the address acquisition unit 152 of the mobile terminal 10 reads and acquires the pairing key displayed on the dial 21. Next, the pairing unit 156 of the mobile terminal 10 performs mutual authentication with the watch 20 using the acquired pairing key, and performs pairing with the watch 20.

  As described above, according to the timepiece 20 including the communication device 200 according to the present embodiment, the combination of numbers indicated by the plurality of hands (the minute hand 22, the second hand 23, the hour hand 24) on the dial 21 is changed over time, The address data is displayed on the dial 21. Then, the mobile terminal 10 reads the address data and automatically connects to the clock 20 of the address data. For this reason, it is not necessary for the clock to advertise a packet including address data, and it is not necessary for the user to select a connection destination from a plurality of clocks on the terminal screen. For this reason, the portable terminal 10 can be connected to the watch 20 to be connected easily and reliably without depending on the communication environment and user operation.

  Further, since the address data is displayed by a plurality of pointers on the dial 21, it is not necessary to mount a non-contact IC, and the watch 20 can be prevented from being enlarged.

  Further, according to the timepiece 20 including the communication device 200 in this embodiment, the minute hand (first hand) 22 indicates whether address data is being displayed or the pairing key is being displayed, and the second hand (second hand) 23 is The digit of the address data is shown, and the hour hand (third pointer) 24 shows the value of the address data. For this reason, address data can be displayed utilizing the physical configuration of the original timepiece 20 (a plurality of pointers on the dial 21) without adding mechanical members or the like when displaying the address data.

  Moreover, according to the timepiece 20 including the communication device 200 in this embodiment, after establishing a connection with the portable terminal 10, the combination of numbers indicated by a plurality of hands on the dial 21 is changed over time to A pairing key for pairing with the terminal 10 is displayed on the dial 21. Then, the mobile terminal 10 reads the pairing key and performs pairing with the watch 20 using the pairing key. This eliminates the need for the watch 20 to broadcast a packet including a pairing key (PIN code), so that the pairing key can be reliably transmitted to the pairing partner regardless of the communication environment. Further, since it is not necessary for the user to directly input the pairing key of the watch 20 into the mobile terminal 10, pairing can be performed automatically and easily regardless of the user operation.

  Although the description of the embodiment has been completed above, the above embodiment is an example, and the specific configurations of the mobile terminal 10 and the clock 20 and the contents of each process are not limited to those described in the above embodiment. Of course.

  In the embodiment described above, the role of each pointer is the role of the minute hand 22 indicating whether the first pointer is displaying address data or the pairing key, and the second hand 23 is indicating the digit of the address data and the pairing key. Although the description has been made on the assumption that the third pointer is the hour hand 24 indicating the address data and the value of the pairing key, the present invention is not limited to this. The division of roles of these guidelines may be interchanged as long as the address data and the pairing key can be displayed. For example, the first hand may be the hour hand 24, the second hand may be the minute hand 22, and the third hand may be the second hand 23. In this case, the hour hand 24 displays one of address data or a pairing key, the minute hand 22 displays a digit, and the second hand 23 displays a value. According to this, since the roles of a plurality of pointers can be appropriately determined according to the type and shape (length, thickness) of the pointers, the division of roles that facilitates reading of the address data pairing key is possible. Can be.

  In the above-described embodiment, the address data display indicates “12” and the pairing key display indicates “6”. However, the present invention is not limited to this. The numbers indicated are design matters and can be determined as appropriate.

  In the above-described embodiment, the mobile terminal 10 performs analysis after capturing a moving image with the camera 13 and acquires the address data and the pairing key of the clock 20, but is not limited thereto. For example, the address acquisition unit 152 of the mobile terminal 10 may perform real-time analysis on a moving image being shot by the user. Thereby, it is possible to reduce the time required for acquiring the address data and the pairing key, rather than analyzing the moving image once stored after shooting. Moreover, since it is not necessary to memorize | store the image | photographed moving image in the memory | storage part 14 of the portable terminal 10, it is suitable for a smart phone etc. with little memory capacity.

  In the above-described embodiment, the timepiece 20 displays the address data and the pairing key using a plurality of hands, but is not limited thereto. For example, the address data may be displayed by a date window number indicating the date on the dial 21 of the clock 20 and a number indicated by a plurality of hands. Specifically, it is conceivable that the digit display is performed with a number in the date window (for example, 1 for 1 digit) instead of the pointer. In this case, the display control unit 211 may switch the date window numbers in ascending order and control the hour hand 24 to be in the area to which the digit value is assigned at the switching timing.

  In the above-described embodiment, the address data and the pairing key are displayed using a plurality of pointers, but the present invention is not limited to this. Any combination of numbers pointed to by multiple hands can be used. For example, a watch with a built-in sensor displays the numerical value indicated by the sensing result (pulse, step count, calorie consumption, etc.) using multiple hands. Also good. As a result, numerical information held by an analog timepiece that does not include a digital display unit can be displayed using a plurality of hands.

  In the above-described embodiment, the description has been made on the assumption that the plurality of hands on the dial 21 of the timepiece 20 are physical mechanical members, but the present invention is not limited to this. For example, the address data may be displayed using a plurality of digitally displayed hands on the digital dial of the digital clock. Thereby, not only an analog timepiece but also a digital timepiece can display address data using a plurality of hands.

The clock 20 has been described on the assumption that it is a wearable wristwatch. However, the address data display according to this embodiment may be applied to a table clock or a wall clock having a Bluetooth function. Thereby, after the table clock or wall clock is paired with the mobile terminal 10, automatic time correction can be performed at an appropriate timing by the GPS function of the mobile terminal 10.
Moreover, although the portable terminal 10 demonstrated on the assumption that it was a smart phone, it should just be provided with the communication function by Bluetooth and Bluetooth, for example, a tablet terminal, a mobile phone, a notebook PC etc. may be sufficient.

In the above-described embodiment, each function (display control unit 211 and communication control unit 212) of the timepiece 20 has been described as a function of the control unit 210. That is, although the case where the CPU configuring the control unit 210 executes each function has been described as an example, the present invention is not limited to this. For example, the above functions may be executed by a BLE LSI (for example, a CPU included in the LSI) constituting the short-range wireless communication unit 216. According to this, the processing load of the main CPU of the timepiece 20 can be suppressed.
In the above-described embodiment, the case where the communication apparatus 200 is built in the timepiece 20 has been described as an example, but the present invention is not limited to this. The communication device 200 can be applied as long as the device includes a plurality of pointers. For example, by applying it as a communication module in an in-vehicle device such as a car or a motorcycle, vehicle information can be displayed by a plurality of pointers on the meter. For example, various information useful for the driver, such as room temperature, remaining amount of gasoline, and speed, can be displayed.

  In addition, the communication device 200 according to the present invention can be realized using a normal computer without using a dedicated device. For example, the communication apparatus 200 may be realized by a computer executing a program. Programs for realizing the functions of the communication device 200 can be read by a computer such as a universal serial bus (USB) memory, a compact disc read only memory (CD-ROM), a digital video disc (DVD), and a hard disk drive (HDD). It may be stored in a simple recording medium or downloaded to a computer via a network.

  As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to the specific embodiment which concerns, This invention includes the invention described in the claim, and its equivalent range It is. Hereinafter, the invention described in the scope of claims of the present application will be appended.

(Appendix 1)
Display control means for controlling the display of address data for uniquely identifying its own device by changing a combination of numbers indicated by a plurality of pointers over time;
Communication control means for controlling connection with another device that has decoded the address data controlled by the display control means;
A communication apparatus comprising:

(Appendix 2)
The display control means includes a first pointer of the plurality of pointers at a predetermined numerical position indicating that the address data is being displayed, and a second pointer at a numerical position indicating the digit of the address data. In addition, the third pointer is displayed and controlled at the position of the area to which the value of the address data is assigned,
The communication apparatus according to supplementary note 1, wherein:

(Appendix 3)
The display control means changes the position of the second pointer in ascending order to the position of the number indicating the digit of the address data while the first pointer is fixed at the position of the predetermined number. Changing the position of the third pointer to an area to which the digit value of the address data is assigned,
The communication apparatus according to Supplementary Note 2, wherein

(Appendix 4)
The address data is a 12-digit hexadecimal number,
Each value of the hexadecimal number is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 16 equal parts,
The communication apparatus according to appendix 3, wherein:

(Appendix 5)
The communication control means includes
Receiving means for receiving a connection request transmitted from another device that has decrypted the address data;
In response to the connection request received by the receiving means, connection establishing means for establishing a connection with the other device;
Comprising
The communication apparatus according to any one of appendices 1 to 4, wherein

(Appendix 6)
The display control means includes a pairing key for pairing with the other apparatus by changing a combination of numbers indicated by the plurality of pointers over time after the connection establishing means establishes a connection with the other apparatus. Control the display of
The communication apparatus according to appendix 5, wherein:

(Appendix 7)
The pairing key is a 6-digit decimal number,
Each value of the decimal number is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 10 equal parts,
The display control means fixes the position of the second pointer in a state in which the first pointer is fixed at a position different from the predetermined number indicating that the pairing key is being displayed. Changing the position of the third pointer to an area to which the value of the digit of the pairing key is assigned, at the same time as
The communication apparatus according to appendix 6, wherein:

(Appendix 8)
The communication control means further includes
A pairing means for pairing with the other device that has acquired the pairing key;
The communication apparatus according to appendix 6 or 7, characterized by the above.

(Appendix 9)
The other device is a mobile terminal having a wireless communication function by Bluetooth (registered trademark),
The address data is a Bluetooth device address,
The communication control means connects to the portable terminal that has photographed the plurality of pointers and read the device address.
9. The communication device according to any one of appendices 1 to 8, wherein

(Appendix 10)
In addition to the address data, the display control means performs display control of a numerical value indicated by a sensing result by a sensor by changing a combination of numbers indicated by the plurality of hands over time.
The communication device according to any one of appendices 1 to 9, characterized in that:

(Appendix 11)
A timepiece comprising the communication device according to any one of appendices 1 to 10.

(Appendix 12)
A display control step for controlling the display of address data for uniquely identifying the device itself by changing a combination of numbers indicated by a plurality of pointers over time;
A communication control step for controlling connection with another device that has decoded the display-controlled address data in the display control step;
A communication method comprising:

(Appendix 13)
Shooting steps to shoot the clock face,
An acquisition step of decoding and acquiring address data that uniquely identifies the clock based on a change over time of a combination of numbers indicated by a plurality of hands on the dial imaged in the imaging step;
A connection step of connecting to the clock of the address data acquired in the acquisition step;
A communication method comprising:

DESCRIPTION OF SYMBOLS 10 ... Portable terminal, 11 ... Display part, 12 ... Operation part, 13 ... Camera, 14 ... Memory | storage part, 15,210 ... Control part, 16,216 ... Short-range wireless communication part, 17 ... Wireless communication part, 18, 27 ... Speaker, 20 ... Clock, 21 ... Dial, 22 ... Minute hand, 23 ... Second hand, 24 ... Hour hand, 25 ... Crown, 26 ... Button, 151 ... Shooting unit, 152 ... Address acquisition unit, 153, 212 ... Communication control unit 154 ... Connection request transmission unit, 155, 214 ... Connection establishment unit, 156,215 ... Pairing unit, 200 ... Communication device, 211 ... Display control unit, 213 ... Connection request reception unit

Claims (13)

Display control means for controlling the display of address data for uniquely identifying its own device by changing a combination of numbers indicated by a plurality of pointers over time;
Communication control means for controlling connection with another device that has decoded the address data controlled by the display control means;
A communication apparatus comprising: The display control means includes a first pointer of the plurality of pointers at a predetermined numerical position indicating that the address data is being displayed, and a second pointer at a numerical position indicating the digit of the address data. In addition, the third pointer is displayed and controlled at the position of the area to which the value of the address data is assigned,
The communication apparatus according to claim 1. The display control means changes the position of the second pointer in ascending order to the position of the number indicating the digit of the address data while the first pointer is fixed at the position of the predetermined number. Changing the position of the third pointer to an area to which the digit value of the address data is assigned,
The communication device according to claim 2. The address data is a 12-digit hexadecimal number,
Each value of the hexadecimal number is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 16 equal parts,
The communication apparatus according to claim 3. The communication control means includes
Receiving means for receiving a connection request transmitted from another device that has decrypted the address data;
In response to the connection request received by the receiving means, connection establishing means for establishing a connection with the other device;
Comprising
The communication device according to any one of claims 1 to 4, wherein The display control means includes a pairing key for pairing with the other apparatus by changing a combination of numbers indicated by the plurality of pointers over time after the connection establishing means establishes a connection with the other apparatus. Control the display of
The communication apparatus according to claim 5. The communication control means includes
Receiving means for receiving a connection request transmitted from another device that has decrypted the address data;
In response to the connection request received by the receiving means, connection establishing means for establishing a connection with the other device;
With
The display control means includes a pairing key for pairing with the other apparatus by changing a combination of numbers indicated by the plurality of pointers over time after the connection establishing means establishes a connection with the other apparatus. Control the display of
The pairing key is a 6-digit decimal number,
Each value of the decimal number is assigned in ascending order to each area obtained by dividing the movable area of the plurality of hands into 10 equal parts,
The display control means fixes the position of the second pointer in a state in which the first pointer is fixed at a position different from the predetermined number indicating that the pairing key is being displayed. Changing the position of the third pointer to an area to which the value of the digit of the pairing key is assigned, at the same time as
The communication apparatus according to any one of claims 2 to 4, wherein the communication apparatus is characterized in that The communication control means further includes
A pairing means for pairing with the other device that has acquired the pairing key;
The communication apparatus according to claim 6 or 7, wherein The other device is a mobile terminal having a wireless communication function by Bluetooth (registered trademark),
The address data is a Bluetooth device address,
The communication control means connects to the portable terminal that has photographed the plurality of pointers and read the device address.
The communication device according to claim 1, wherein the communication device is a device. In addition to the address data, the display control means performs display control of a numerical value indicated by a sensing result by a sensor by changing a combination of numbers indicated by the plurality of hands over time.
The communication device according to claim 1, wherein the communication device is a device.   A timepiece comprising the communication device according to claim 1. A display control step for controlling the display of address data for uniquely identifying the device itself by changing a combination of numbers indicated by a plurality of pointers over time;
A communication control step for controlling connection with another device that has decoded the display-controlled address data in the display control step;
A communication method comprising: Shooting steps to shoot the clock face,
An acquisition step of decoding and acquiring address data that uniquely identifies the clock based on a change over time of a combination of numbers indicated by a plurality of hands on the dial imaged in the imaging step;
A connection step of connecting to the clock of the address data acquired in the acquisition step;
A communication method comprising:

Images