CN110321993B - Count information updating method, electronic system and portable electronic device - Google Patents

Abstract

The embodiment of the invention provides a counting information updating method, which is used for an electronic system, wherein the electronic system comprises a display and a portable electronic device, the portable electronic device comprises at least one sensor and a plurality of spheres connected in series, the sensor is arranged on at least one first sphere in the spheres, and the method comprises the following steps: sensing a physical action on the sphere via the sensor and generating a sensing signal; estimating the number of times of sphere stirring corresponding to the sphere according to the sensing signal; and updating counting information according to the stirring times of the ball body and displaying the counting information on the display. In addition, the invention also provides a corresponding electronic system and a portable electronic device.

Description

Count information updating method, electronic system and portable electronic device

Technical Field

The present invention relates to electronic devices, and particularly to a method for updating count information, an electronic system and a portable electronic device.

Background

Generally, some people wear candles made of wood or plastic, and have no electronic operation function. When a user dials a candidiasis and recites the candidiasis at the same time, the user may need to count time or recite the exercise in the heart by matching with a watch, so that the user is easily distracted and the counted recite times are often inaccurate.

Disclosure of Invention

The invention provides a counting information updating method, an electronic system and a portable electronic device, which can automatically update counting information related to the stirring of the portable electronic device.

An embodiment of the invention provides a method for updating count information, which is used for an electronic system, the electronic system comprises a display and a portable electronic device, the portable electronic device comprises at least one sensor and a plurality of spheres connected in series, the sensor is arranged on at least one first sphere in the spheres, and the method for updating count information comprises the following steps: sensing a sphere toggle operation acting on the sphere via the sensor and generating a sensing signal; estimating the number of times of sphere stirring corresponding to the sphere according to the sensing signal; and updating counting information according to the stirring times of the ball body and displaying the counting information on the display.

An embodiment of the invention provides an electronic system, which comprises a display device and a portable electronic device. The display device has a processor and a display. The portable electronic device is wirelessly connected to the display device. The portable electronic device comprises at least one sensor and a plurality of spheres connected in series, wherein the sensor is arranged on at least one first sphere in the spheres, and is used for sensing sphere stirring operation acted on the spheres and generating sensing signals. The processor is used for estimating the sphere stirring times corresponding to the sphere according to the sensing signal, updating the counting information according to the sphere stirring times and displaying the counting information on the display.

An embodiment of the invention provides a portable electronic device, which comprises a plurality of spheres, at least one sensor, a display and a processor, wherein the spheres are connected in series. The sensor is arranged on at least one first sphere in the spheres. The processor is connected with the sensor and the display, wherein the sensor is used for sensing sphere stirring operation acting on the sphere and generating a sensing signal. The processor is used for estimating the sphere stirring times corresponding to the sphere according to the sensing signal, updating the counting information according to the sphere stirring times and displaying the counting information on the display.

Based on the above, by providing a sensor in a portable electronic device including a plurality of balls connected in series with each other, when the balls are shifted (or rotated), the sensor can sense the motion of an object acting on the balls and generate a corresponding sensing signal. According to the sensing signal, the number of times the sphere corresponding to the sphere is toggled can be estimated and used for updating the counting information displayed on the display. Therefore, if the user dials the ball of the portable electronic device once by orally reciting the inscription once, the user can easily learn that he recites the inscription for several times in the past period of time according to the counting information, thereby increasing the achievement sense and/or convenience when reciting.

In order to make the above features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

Drawings

Fig. 1 is a schematic diagram of an electronic system according to an embodiment of the invention.

FIG. 2 is a functional block diagram of an electronic system according to an embodiment of the invention.

Fig. 3 is a schematic diagram illustrating a sphere toggle operation according to an embodiment of the present invention.

Fig. 4 is a schematic diagram of a sphere for poking a portable electronic device according to an embodiment of the present invention.

FIG. 5 is a schematic diagram showing a sphere toggling operation corresponding to a sensed voltage change according to an embodiment of the present invention.

Fig. 6 is a schematic diagram showing display count information according to an embodiment of the present invention.

Fig. 7 is a schematic diagram showing display count information according to another embodiment of the present invention.

Fig. 8 is a flowchart illustrating a count information updating method according to an embodiment of the present invention.

Fig. 9 is a schematic diagram of a portable electronic device according to an embodiment of the invention.

Description of the reference numerals

10: an electronic system;

11: an electronic device;

12. 92: a portable electronic device;

101: connecting wires;

121. 122 (1) to 122 (13), 921, 922 (1) to 922 (13): a sphere;

201. 901: a display;

202. 212: a memory circuit;

203. 213: a communication circuit;

204. 214: a power supply circuit;

205. 215: a processor;

211: a sensor;

301: a user's hand;

401: the direction of the sphere;

402: a reference direction;

403 (1) to 403 (14): an included angle;

410 (1) to 410 (14), 410 (n): the sphere is operated by stirring;

501: sensing a signal;

602. 701: a count information display interface;

611. 711, 712: counting information;

612: auxiliary information;

s801 to S803: and (3) step (c).

Detailed Description

Fig. 1 is a schematic diagram of an electronic system according to an embodiment of the invention. Referring to fig. 1, an electronic system 10 includes an electronic device 11 and a portable electronic device 12. The electronic device 11 can communicate with the portable electronic device 12 via the connection 101 in a wired or wireless manner. In the present embodiment, the electronic device 11 is exemplified by a smart phone. However, in another embodiment, the electronic device 11 may also be a portable computing device with communication, operation, storage and display functions, such as a tablet computer, a notebook computer, etc. Alternatively, in another embodiment, the electronic device 11 may be a (non-portable) computing device with communication, operation, storage and display functions, such as a desktop computer, an industrial computer or a server host.

The portable electronic device 12 has a shape resembling a candid bracelet or a candid necklace as shown in fig. 1. For example, the portable electronic device 12 is adapted to be worn by a user on a bowl or neck. The portable electronic device 12 has a plurality of balls 121 and 122 (1) to 122 (13). In this embodiment, the total number of spheres 121 and 122 (1) to 122 (13) is 14. However, in another embodiment, the total number of the balls 121 and 122 (1) -122 (13) may be more or less, and the invention is not limited thereto. The spheres 121 and 122 (1) to 122 (13) are connected to each other by elastic or inelastic threads. In the present embodiment, the exterior of each of the spheres 121 and 122 (1) to 122 (13) is a circular sphere. However, in another embodiment, the shape of one of the spheres 121 and 122 (1) to 122 (13) may be elliptic, cylindrical, stereo-conical or stereo-rectangular, etc., and the present invention is not limited thereto.

In the present embodiment, the sphere 121 is also referred to as a first sphere, and the spheres 122 (1) to 122 (13) are also referred to as second spheres. In this embodiment, the total number of first spheres is 1, and the total number of second spheres is 13. However, in another embodiment, the total number of the first spheres and the total number of the second spheres may be more or less, and the present invention is not limited thereto.

In this embodiment, the spheres 122 (1) to 122 (13) are substantially the same in size (e.g., radius and/or surface area), and the sphere 121 is larger in size (e.g., radius and/or surface area) than any of the spheres 122 (1) to 122 (13). In another embodiment, the spheres 121 and 122 (1) -122 (13) may also be substantially the same, at least partially the same, or at least partially different in size (e.g., radius and/or surface area). In this embodiment, the sphere 121 and the spheres 122 (1) to 122 (13) are hollow spheres. However, in another embodiment, sphere 121 is a hollow sphere, and at least one of spheres 122 (1) -122 (13) may be a solid sphere.

In the present embodiment, the main constituent materials of the spheres 122 (1) to 122 (13) are the same, and the main constituent material of the sphere 121 may be different from that of any one of the spheres 122 (1) to 122 (13). For example, the main constituent material of the spheres 122 (1) to 122 (13) may be wood, and the main constituent material of the sphere 121 may not include wood. Furthermore, in another embodiment, the main constituent materials of at least two of spheres 121 and 122 (1) -122 (13) may be the same. In one embodiment, the main constituent materials of the sphere 121 and any one of the spheres 122 (1) to 122 (13) may further include various metals or non-metals such as plastics, pressure grams, etc., which is not limited by the present invention.

FIG. 2 is a functional block diagram of an electronic system according to an embodiment of the invention. Referring to fig. 1 and 2, the electronic device 11 includes a display 201, a memory circuit 202, a communication circuit 203, a power circuit 204, and a processor 205. The display 201, the memory circuit 202, the communication circuit 203, and the power circuit 204 are all connected to the processor 205. The display 201 is used to display an image. For example, the Display 201 may be a liquid crystal Display (Liquid Crystal Display, LCD), a Light-Emitting Diode (LED) Display, an organic electroluminescence Display (Organic Light Emitting Display, OLED), an electrophoretic Display (EPD), or other types of displays. In addition, the display 201 may or may not support touch functions, and the invention is not limited thereto.

The memory circuit 202 is used for storing data. For example, the storage circuitry 202 may include volatile storage media and non-volatile storage media. The volatile storage medium may be a random access memory, and the nonvolatile storage medium may be a read-only memory, a solid state disk, or a conventional hard disk.

The communication circuit 203 is used for communicating with the portable electronic device 12 via the connection line 101. For example, the communication circuit 203 may comprise a wired or wireless network card. For example, the communication circuit 203 may support wireless communication protocols such as WIFI, bluetooth (Bluetooth), bluetooth low energy (Bluetooth Low Energy, BLE), long Term Evolution (LTE), or wired communication protocols such as Ethernet (Ethernet) to establish the connection 101. The power circuit 204 is used for providing power required by the operation of the electronic device 11. For example, the power circuit 204 may include a battery or various power supplies.

The processor 205 is used for controlling the display 201, the storage circuit 202 and the communication circuit 203 to perform communication, operation, storage and display functions. For example, the processor 205 may be a central processing unit, a graphics processor (graphics processing unit, GPU) or other programmable general purpose or special purpose microprocessor, a digital signal processor, a programmable controller, an application specific integrated circuit, a programmable logic device, or other similar device or combination of devices. In another embodiment, the processor 205 may also control the electronic device 11 to perform other functions or tasks, the invention is not limited by the present invention.

The portable electronic device 12 includes a sensor 211, a memory circuit 212, a communication circuit 213, a power circuit 214, and a processor 215. The sensor 211, the memory circuit 212, the communication circuit 213, and the power circuit 214 are all connected to the processor 215. The sensor 211, the memory circuit 212, the communication circuit 213, the power circuit 214, and the processor 215 are all disposed on the sphere 121 (i.e., the first sphere). In an embodiment, if the number of first spheres is greater than 1, any one of the sensor 211, the storage circuit 212, the communication circuit 213, the power circuit 214, and the processor 215 may be disposed in a dispersed manner on the plurality of first spheres. In one embodiment, the sensor 211 may also be disposed on one or more second spheres.

The sensor 211 may sense a physical action (also referred to as a sphere toggle operation) acting on at least one of the spheres 121 and 122 (1) -122 (13) and generate a sensing signal. For example, the sensor 211 may include at least one of a gravity sensor, an acceleration sensor, a magnetic sensor, a gyroscope, a distance sensor, a light sensor, a capacitance sensor, a resistance sensor, and a pressure sensor. In addition, the number of the sensors 211 may be one or more, and the present invention is not limited thereto.

The memory circuit 212 is used for storing data. For example, the storage circuitry 212 may include volatile storage media and non-volatile storage media. The volatile storage medium may be a random access memory, and the nonvolatile storage medium may be a read-only memory or a solid state disk.

The communication circuit 213 is used to communicate with the electronic device 11 (or the communication circuit 203) via the connection 101. For example, the communication circuit 213 may include a wired or wireless network card. For example, the communication circuit 213 may support a wireless communication protocol such as WIFI, bluetooth low energy, or long term evolution, or a wired communication protocol such as ethernet to establish the connection 101.

The power circuit 214 is used for providing power required by the portable electronic device 12. For example, the power circuit 214 may include a battery or various power supplies. In the present embodiment, the power circuit 214 further has a wireless charging circuit to support a wireless charging function.

The processor 215 is used for controlling the sensor 211, the storage circuit 212 and the communication circuit 213 to perform sensing, communication, operation and storage functions. For example, the processor 215 may be a central processing unit, a graphics processor, an embedded controller, or other programmable general purpose or special purpose microprocessor, a digital signal processor, a programmable controller, an application specific integrated circuit, a programmable logic device, or other similar device, or a combination of such devices. In another embodiment, the processor 215 may also control the portable electronic device 12 to perform other functions or tasks, the invention is not limited.

Fig. 3 is a schematic diagram illustrating a sphere toggle operation according to an embodiment of the present invention. Referring to fig. 1 to 3, when the hand 301 of the user holds the portable electronic device 12 and dials (i.e. rotates) the ball of the portable electronic device 12 with a finger, the sensor 211 of the portable electronic device 12 can sense the ball-toggling operation applied to the balls 121 and 122 (1) to 122 (13) and generate a sensing signal. The sensing signal may reflect a change in an angle between the sphere direction of sphere 121 (or any of spheres 122 (1) -122 (13)) and a reference direction. In one embodiment, the sensing signal is generated in response to a change in the angle between the sphere direction of sphere 121 (or any of spheres 122 (1) -122 (13)) and the reference direction.

In one embodiment, the processor 215 of the portable electronic device 12 can estimate the number of toggles (also referred to as the ball toggling number) corresponding to the balls 121 and 122 (1) to 122 (13) according to the sensing signal. Taking fig. 3 as an example, the number of times the ball is toggled reflects the number of times the user's hand 301 toggles the balls 121 and 122 (1) through 122 (13) sequentially with respect to the centers of the balls 121 and 122 (1) through 122 (13). The processor 215 may then transmit the ball toggle times to the electronic device 11 in packets via the communication circuit 213. The processor 205 of the electronic device 11 may receive the ball striking number from the portable electronic device 12 via the communication circuit 203 and update the count information according to the ball striking number. The processor 205 may then display the updated count information on the display 201.

In one embodiment, the sensor 211 may sense information related to the angular change of the sphere, such as the gravity change, acceleration change, magnetic field change, and/or angular velocity change of the sphere 121, and generate a corresponding sensing signal. The processor 215 of the portable electronic device 12 can analyze the sensing signal to obtain the angle information of the sphere 121. If the angle information reflects that the change of the angle between the sphere direction of the sphere 121 and the reference direction meets a predetermined condition, the processor 215 may add a predetermined value to the sphere toggle number to update the sphere toggle number.

Fig. 4 is a schematic diagram of a sphere for poking a portable electronic device according to an embodiment of the present invention. Referring to fig. 4, assume that an angle (also referred to as an initial angle) 403 (1) between a sphere direction 401 of the sphere 121 and a reference direction 402 is, for example, 90 degrees. The sphere direction 401 will change as spheres 121 and 122 (1) through 122 (13) are shifted. More specifically, the sphere direction 401 is a basis for identifying that the sphere 121 is being toggled or rotated. The reference direction 402 may be, for example, a horizontal direction or a predetermined direction, and the reference direction 402 does not change as the spheres 121 and 122 (1) to 122 (13) are shifted.

After the user performs the sphere toggle operation 410 (1) in a similar manner to fig. 3, the angle between the sphere direction 401 of the sphere 121 and the reference direction 402 is changed to the angle 403 (2), and the angle of the angle 403 (2) is smaller than the angle of the angle 403 (1). In one embodiment, if the preset conditions set include that the angle between the sphere direction 401 of the sphere 121 and the reference direction 402 is changed from the angle 403 (1) to the angle 403 (2), the number of sphere toggles may be increased by 1, which indicates that the user toggles (or rotates) the sphere 121 once. Similarly, if the preset conditions include that the angle between the sphere direction 401 of the sphere 121 and the reference direction 402 is changed from the angle 403 (2) to the angle 403 (3), the sphere toggle operation 410 (2) is performed, and then the number of sphere toggles may be increased by 1 again, which indicates that the user toggles (or rotates) the sphere 121 once again.

After the user performs 14 ball toggling operations 410 (1) to 410 (14), the angle between the ball direction 401 of the ball 121 and the reference direction 402 is sequentially changed from the angle 403 (2) to the angle 403 (14) and back to the angle 403 (1). According to the preset condition, 14 balls can be added with 1 to the number of ball toggling, which indicates that the user continuously toggles (or rotates) the ball 121 14 times.

In one embodiment, if the change of the included angle between the sphere direction 401 and the reference direction 402 of the sphere 121 matches a reference angle change, it may also be determined that the change of the included angle between the sphere direction and the reference direction of the sphere 121 matches a predetermined condition. For example, the reference angle change may refer to an increase (or decrease) of the angle between the sphere direction 401 and the reference direction 402 by a reference angle. Taking the example of FIG. 4, this reference angle may be about 6.4 degrees (90/14). When the change in the angle between the sphere direction 401 of the sphere 121 and the reference direction 402 is reduced by changing from the angle 403 (1) to the angle 403 (2), the number of sphere toggles may be increased by 1.

In an embodiment, the preset value may also be a positive integer greater than 1. Taking the preset value as 14 as an example, after determining that the included angle between the sphere direction 401 of the sphere 121 and the reference direction 402 sequentially changes from the initial included angle 403 (1) to the included angle 403 (14) and back to the included angle 403 (1), the number of sphere strokes may be added 14 at a time, which indicates that the user continuously toggles (or rotates) the sphere 121 14 times. In addition, the preset value may be set to other positive integers, as long as the preset conditions set are adjusted accordingly. For example, assuming that the preset value is set to 7, when the angle between the sphere direction 401 of the sphere 121 and the reference direction 402 changes from the angle 403 (1) to the angle 403 (8) and 7 reference angles change, the number of sphere strokes may be increased by 7 at a time, which indicates that the user continuously toggles (or rotates) the sphere 121 14 times.

In one embodiment, the sensor 211 can sense a touch, a shock, a light intensity change, a capacitance change, a resistance change, or a pressure change generated by a user toggling the sphere 121 (or any one of the spheres 122 (1) -122 (13)) and generate a corresponding sensing signal. The processor 215 of the portable electronic device 12 can analyze the sensing signal to obtain pulse count information corresponding to the sphere 121 (or any of the spheres 122 (1) -122 (13)). The pulse count information reflects the number of at least one pulse in the sensing signal, which meets a predetermined electrical condition. The processor 215 may update the number of ball toggles based on the pulse count information.

FIG. 5 is a schematic diagram showing a sphere toggling operation corresponding to a sensed voltage change according to an embodiment of the present invention. Referring to fig. 1, 3 and 5, it is assumed that each time the user dials the ball 121 (or any one of the balls 122 (1) -122 (13)) a pulse with a voltage greater than the threshold voltage VT is induced on the sensing signal 501 due to touch, vibration, light intensity variation, capacitance variation, resistance variation or pressure variation. One pulse with a voltage greater than the threshold voltage VT is a pulse wave that meets the preset electrical condition. Taking fig. 5 as an example, assuming that the user continuously performs n sphere toggling operations 410 (1) -410 (n), n pulses with voltages greater than the threshold voltage VT may appear on the sensing signal 501. By analyzing the sensing signal 501, pulse count information can be generated according to the number n. For example, the pulse count information may be set to n. Based on the pulse count information, the number of ball strokes may be added n, indicating that the user has continuously toggled (or rotated) the ball 121 (or any one of the balls 122 (1) to 122 (13)) n times.

It should be noted that, in one embodiment, the operation of estimating the number of ball strokes corresponding to the balls 121 and 122 (1) -122 (13) according to the sensing signal may also be performed by the processor 205 of the electronic device 11. For example, after the sensor 211 of the portable electronic device 12 generates the sensing signal, the processor 215 of the portable electronic device 12 may transmit the sensing signal to the electronic device 11 in a packet form through the communication circuit 213. After the communication circuit 203 of the electronic device 11 receives the sensing signal from the portable electronic device 12, the processor 205 of the electronic device 11 can analyze the sensing signal to estimate the number of times the ball is toggled. Details of the operation of analyzing the sensing signal to estimate the number of toggles of the ball are described above, and will not be repeated here.

Fig. 6 is a schematic diagram showing display count information according to an embodiment of the present invention. Referring to fig. 1 and 6, a count information display interface 602 may be displayed on the display 201. Count information 611 may be presented in count information display interface 602 to indicate that the user has rotated (i.e., toggled) the candidiasis several times. For example, the count information 611 is preset to 0. After the user has performed at least one ball toggle operation, the count 611 may be updated, for example, to 30, based on the estimated number of ball toggles, indicating that the user has rotated the candles 30 times in succession. In one embodiment, if the user recites a script every time he rotates (i.e., dials) the candles (i.e., spheres 121 and 122 (1) -122 (13)), the user can learn that several scripts were recited in the past, based on the automatically updated count information 611, thereby improving the feeling of success of reciting.

In an embodiment, the count information display interface 602 may also present auxiliary information 612. The auxiliary information 612 may be updated synchronously in response to the count information 611 being updated. For example, when the value of the count information 611 is smaller than a preset value (e.g., 10), the auxiliary information 612 may be first graphic information (e.g., lotus flowers that have not yet flowering). When the value of the count information 611 is updated to be greater than this preset value, the auxiliary information 612 may be automatically updated to the second graphic information (e.g., the lotus flower that has already flowering). Thus, the user can further obtain more mental satisfaction according to the change of the auxiliary information 612.

Fig. 7 is a schematic diagram showing display count information according to another embodiment of the present invention. Referring to fig. 1 and 7, in one embodiment, a count information display interface 701 may be displayed on the display 201. The count information display interface 701 may present count information 711 and 712. The count information 711 (also referred to as a single count information or a first count information) is automatically updated according to the rotation (or toggle) of the portable electronic device 12 by the user, so as to indicate that the balls 121 and 122 (1) to 122 (13) on the single rotation (or toggle) by the user are rotated several times (e.g. 50 times).

It should be noted that the count information 712 (also referred to as community count information) is representative of how many times the community turns (or dials) the candid. For example, in one embodiment of fig. 2, the communication circuit 203 may download count information (also referred to as second count information) corresponding to other portable electronic devices (similar to the portable electronic device 12) from a network (e.g., the Internet). The second count information reflects the execution times of the sphere toggle operation acted on other portable electronic devices. That is, the second count information may reflect that the other person or persons have rotated the sphere of the other portable electronic device several times within a certain time range. After obtaining the second count information, the processor 205 may update the count information 712 based on the first count information and the second technical information. For example, assuming that the second count information received by the other 3 portable electronic devices is 200, 600, and 150, respectively, the processor 205 may update the count information 712 to 1000 (200+600+150+50=1000) according to the sum of the values of the first count information and the second count information.

In one embodiment, the processor 205 may also transmit the count information 711 to a network via the communication circuit 203 for other electronic devices (similar to the electronic device 11) or servers to count community count information. In one embodiment, the communication circuit 203 may also receive the group count information counted and provided by the server from the network, so as to achieve the purpose of updating the group count information according to the first count information and the second count information.

In an embodiment, the portable electronic device 12 and the electronic device 11 can also perform the functions of heartbeat detection, walking step number calculation, walking mileage calculation, walking heat consumption calculation, etc. of the user according to the sensing signal of the sensor 211. The relevant detection/calculation results may also be presented on the display 201.

Fig. 8 is a flowchart illustrating a count information updating method according to an embodiment of the present invention. Referring to fig. 8, in step S801, a physical action of a sphere acting on the portable electronic device (i.e., a sphere toggle operation) is sensed by a sensor of the portable electronic device and a sensing signal is generated. In step S802, the sensing signal is analyzed to estimate a sphere toggle number corresponding to the sphere. In step S803, the count information is updated according to the number of times the ball is toggled and displayed on the display.

However, the steps in fig. 8 are described in detail above, and will not be described again here. It should be noted that each step in fig. 8 may be implemented as a plurality of program codes or circuits, and the present invention is not limited thereto. In addition, the method of fig. 8 may be used with the above exemplary embodiment, or may be used alone, and the present invention is not limited thereto.

Fig. 9 is a schematic diagram of a portable electronic device according to an embodiment of the invention. Referring to fig. 9, in the present embodiment, the portable electronic device 92 has a plurality of balls 921 and 922 (1) to 922 (13). The circuit configuration of the portable electronic device 92 is the same or similar to the circuit configuration of the portable electronic device 12 of fig. 1 and 2. It should be noted that the portable electronic device 92 further has a display 901. For example, the display 901 may be arranged on a sphere 921 which is a first sphere. In one embodiment, after the processor of the portable electronic device 92 updates the count information, the display 901 can display the updated count information in real time. In addition, the portable electronic device 92 of fig. 9 and/or the portable electronic device 12 of fig. 1 may further be configured with other input/output interfaces, such as a speaker, a microphone, and/or a vibrator to provide voice input/output, vibration output, etc., according to the actual requirements, the present invention is not limited thereto.

In summary, by providing the sensor in the portable electronic device including the balls connected in series, when the balls are shifted (or rotated), the sensor can sense the motion of the object acting on the balls and generate the corresponding sensing signal. According to the sensing signal, the number of times the sphere corresponding to the sphere is toggled can be estimated and used for updating the counting information displayed on the display. Therefore, if the user dials the ball of the portable electronic device once by orally reciting the inscription once, the user can easily learn that he recites the inscription for several times in the past period of time according to the counting information, thereby increasing the achievement sense and/or convenience when reciting.

Although the invention has been described with reference to the above embodiments, it should be understood that the invention is not limited thereto, but rather may be modified or altered somewhat by persons skilled in the art without departing from the spirit and scope of the invention.

Claims (9)

1. The utility model provides a count information updating method which is characterized in that, is used for electronic system, electronic system includes display and portable electron device, portable electron device includes at least one sensor and a plurality of spheroids that concatenate each other, at least one sensor sets up in at least a first spheroid in a plurality of spheroids, and the count information updating method includes:

sensing sphere toggle operations on the plurality of spheres via the at least one sensor and generating a sensing signal;

obtaining angle information of the at least one first sphere according to the sensing signal;

if the angle information reflects that the change of the included angle between the sphere direction of the at least one first sphere and the reference direction accords with a preset condition, adding a preset value to the sphere stirring times corresponding to the spheres, wherein the sphere stirring times reflect the times that a user sequentially stirs the spheres by taking the centers of the spheres as the reference; and

and updating first counting information according to the stirring times of the ball body and displaying the first counting information on the display.

2. The count information updating method according to claim 1, further comprising:

obtaining pulse wave counting information according to the sensing signal, wherein the pulse wave counting information reflects the number of at least one pulse wave meeting a preset electrical condition in the sensing signal; and

and estimating the number of times of stirring the spheres corresponding to the spheres according to the pulse wave counting information.

3. The count information updating method according to claim 1, further comprising:

updating group counting information according to the first counting information and the second counting information, wherein the second counting information reflects the execution times of sphere stirring operation acted on another portable electronic device; and

and displaying the group counting information on the display.

4. An electronic system, comprising:

a display device having a processor and a display; and

a portable electronic device, which is connected with the display device in a wireless way,

wherein the portable electronic device comprises at least one sensor and a plurality of spheres connected in series, the at least one sensor is arranged on at least one first sphere in the spheres,

the at least one sensor is used for sensing sphere poking operation on the spheres and generating a sensing signal,

the processor is used for obtaining the angle information of the at least one first sphere according to the sensing signal,

if the angle information reflects that the change of the included angle between the sphere direction of the at least one first sphere and the reference direction meets the preset condition, the processor adds the sphere toggle times corresponding to the spheres to a preset value, wherein the sphere toggle times reflect the times that a user toggles the spheres in sequence by taking the centers of the spheres as the reference, and

and the processor updates first counting information according to the stirring times of the ball body and displays the first counting information on the display.

5. The electronic system of claim 4, wherein the processor is further to:

obtaining pulse wave counting information according to the sensing signal, wherein the pulse wave counting information reflects the number of at least one pulse wave meeting a preset electrical condition in the sensing signal; and

and estimating the number of times of stirring the spheres corresponding to the spheres according to the pulse wave counting information.

6. The electronic system of claim 4, wherein the processor is further configured to update group count information according to the first count information and a second count information, and display the group count information on the display, wherein the second count information reflects a number of times of execution of a sphere toggle operation applied to another portable electronic device.

7. A portable electronic device, comprising:

a plurality of spheres connected in series with each other;

at least one sensor arranged on at least one first sphere of the plurality of spheres;

a display; and

a processor connected with the at least one sensor and the display,

wherein the at least one sensor is used for sensing sphere toggle operation on the plurality of spheres and generating a sensing signal,

the processor is used for obtaining the angle information of the at least one first sphere according to the sensing signal,

if the angle information reflects that the change of the included angle between the sphere direction of the at least one first sphere and the reference direction meets the preset condition, the processor adds the sphere toggle times corresponding to the spheres to a preset value, wherein the sphere toggle times reflect the times that a user toggles the spheres in sequence by taking the centers of the spheres as the reference, and

and the processor updates first counting information according to the stirring times of the ball body and displays the first counting information on the display.

8. The portable electronic device of claim 7, wherein the processor is further configured to:

obtaining pulse wave counting information according to the sensing signal, wherein the pulse wave counting information reflects the number of at least one pulse wave meeting a preset electrical condition in the sensing signal; and

and estimating the number of times of stirring the spheres corresponding to the spheres according to the pulse wave counting information.

9. The portable electronic device of claim 7, wherein the processor is further configured to update group count information according to the first count information and second count information, and display the group count information on the display, wherein the second count information reflects a number of times of execution of a sphere toggle operation applied to another portable electronic device.