阅读说明：本技术 健身器材及其控制方法 (Fitness equipment and control method thereof ) 是由 周信宽 施智轩 于 2018-08-01 设计创作，主要内容包括：一种健身器材,包括：无线通信组件,用于发射和接收无线信号；以及处理器,用于通过所述无线通信组件接收运动菜单,并根据所述运动菜单设定所述健身器材的运动程序,所述运动菜单是根据用户的生理资讯而生成,所述运动菜单包括运动速度、运动强度和运动时长其中至少一者。本发明还提供一种健身器材的控制方法。(An exercise apparatus comprising: a wireless communication component for transmitting and receiving wireless signals; and the processor is used for receiving a motion menu through the wireless communication component and setting a motion program of the fitness equipment according to the motion menu, the motion menu is generated according to physiological information of a user, and the motion menu comprises at least one of motion speed, motion intensity and motion duration. The invention also provides a control method of the fitness equipment.)

1. An exercise apparatus, characterized in that the exercise apparatus comprises:

a wireless communication component for transmitting and receiving wireless signals; and

the processor is used for receiving a sports menu through the wireless communication component and setting a sports program of the fitness equipment according to the sports menu, the sports menu is generated according to physiological information of a user, and the sports menu comprises at least one of sports speed, sports intensity and sports duration.

2. The exercise apparatus of claim 1, wherein the processor is further configured to receive the physiological information from the wearable device via the wireless communication component, transmit the physiological information to a server via the wireless communication component, and receive the exercise menu from the server via the wireless communication component, the exercise menu being generated based on the historical exercise menu of the user and the physiological information.

3. The exercise apparatus of claim 1, wherein the physiological information includes at least one of a frequency of heartbeats, a length of sleep, and a quality of sleep of the user.

4. An exercise apparatus according to claim 1, wherein said processor is further configured to determine whether an activation signal or a deactivation signal has been received, said processor being further configured to activate said exercise apparatus upon receipt of said activation signal and deactivate said exercise apparatus upon receipt of said deactivation signal.

5. An exercise apparatus according to claim 4, wherein said processor is further configured to receive a frequency of movement of said user, said processor being further configured to adjust said exercise program based on said frequency of movement.

6. An exercise apparatus according to claim 5, wherein said processor receives said activation signal, said deactivation signal, and said exercise frequency from a wearable device via said wireless communication component.

7. An exercise apparatus according to claim 5, wherein said exercise apparatus further comprises a sensor for detecting said exercise frequency and generating said activation signal and said deactivation signal based on said exercise frequency.

8. A control method of fitness equipment is applied to the fitness equipment and is characterized by comprising the following steps:

receiving a motion menu, wherein the motion menu is generated according to the physiological information of a user; and

setting a motion program of the fitness equipment according to the motion menu;

wherein the motion menu comprises at least one of a motion speed, a motion intensity and a motion duration.

9. The exercise apparatus control method of claim 8, wherein the exercise menu is generated based on the user's historical exercise menu and the physiological information.

10. The exercise apparatus control method of claim 8, wherein the physiological information includes at least one of a frequency of heart beats, a length of sleep time, and a quality of sleep of the user.

11. The exercise apparatus control method of claim 8, further comprising:

judging whether a starting signal or a stopping signal is received, starting the fitness equipment after the starting signal is received, and stopping the fitness equipment after the stopping signal is received.

12. The exercise apparatus control method of claim 8, further comprising:

receiving a motion frequency of the user; and

and adjusting the motion program according to the motion frequency.

13. The exercise apparatus control method of claim 12, further comprising:

and detecting the motion frequency, and generating the starting signal and the stopping signal according to the motion frequency.

Technical Field

The invention relates to an automatic control technology, in particular to fitness equipment and a control method thereof.

Background

With the improvement of living standard, people pay more and more attention to the health, and can obviously strengthen the physique by proper exercise. There are many types of existing exercise modes, and exercise in a gymnasium becomes the choice of most people. The existing fitness equipment is provided with a physical stop key, and when a user feels that the body is not proper, the user can press the stop key to stop the fitness equipment. Meanwhile, the partial fitness equipment on the market is also provided with a magnetic induction technology, and when a user has an emergency, the user can press the pause key to stop the fitness equipment. However, these fitness equipments require the user to control the start and stop, so that the automatic control cannot be realized, and meanwhile, the exercise program cannot be automatically set in combination with the physiological state of the user, thereby reducing the user experience.

Disclosure of Invention

In view of this, a fitness apparatus and a control method thereof are provided, which can automatically set a motion program in combination with a physiological state of a user, thereby improving the convenience and intellectualization of manipulation of the fitness apparatus.

One embodiment of the present invention provides a fitness apparatus comprising:

a wireless communication component for transmitting and receiving wireless signals; and

the processor is used for receiving a sports menu through the wireless communication component and setting a sports program of the fitness equipment according to the sports menu, the sports menu is generated according to physiological information of a user, and the sports menu comprises at least one of sports speed, sports intensity and sports duration.

One embodiment of the present invention provides a control method for fitness equipment, including:

receiving a motion menu, wherein the motion menu is generated according to the physiological information of a user; and

setting a motion program of the fitness equipment according to the motion menu;

wherein the motion menu comprises at least one of a motion speed, a motion intensity and a motion duration.

The fitness equipment and the control method thereof can automatically set the exercise program by combining the physiological state of the user, and improve the operation convenience and the intellectualization of the fitness equipment.

Drawings

FIG. 1 is a functional block diagram of an exercise system according to one embodiment of the present invention.

FIG. 2 is a functional block diagram of an exercise apparatus according to an embodiment of the present invention.

Fig. 3 is a functional block diagram of a server according to an embodiment of the present invention.

Figure 4 is a flow chart illustrating the steps of a method for controlling exercise equipment in accordance with another embodiment of the present invention.

Description of the main elements

Fitness system	100
		Fitness equipment control system	200
Body-building apparatus	30
		Mobile device	40
Server	50
		Wearable device	60
First memory	70
		Second memory	72
First processor	80
		Second processor	82
First wireless communication module	90
		Second wireless communication module	92
Setting module	31
		Judging module	32
Motion menu generation module	35

Detailed Description

Referring to fig. 1, in one embodiment, an exercise system 100 includes an exercise apparatus 30, a mobile device 40, and a server 50. The exercise apparatus 30 and the mobile device 40 are connected to each other through a wireless network (e.g., WIFI, bluetooth) or Near Field Communication (NFC) to transfer information. The exercise apparatus 30 may be a treadmill, a body building vehicle, a waist-building machine, or other exercise apparatuses. The mobile device 40 may be an electronic device such as a mobile phone and a tablet computer. The exercise apparatus 30 and the mobile device 40 may be communicatively coupled to a server 50 via a wired network and/or a wireless network. The server 50 may be a computer host, a computer, a cloud server, or other devices that can store and execute code and data. The exercise apparatus 30 and the mobile device 40 can also be connected to a wearable device 60 via a wireless network (e.g., WIFI, bluetooth) or Near Field Communication (NFC) to obtain user information.

In one embodiment, the mobile device 40 communicates with the wearable device 60 to obtain physiological information of the user. The mobile device 40 sends the acquired physiological information to the server 50, and the server 50 generates a motion menu according to the received physiological information and transmits the motion menu back to the mobile device 40. The mobile device 40 then transmits the exercise menu to the exercise apparatus 30, and the exercise apparatus 30 sets an exercise program according to the exercise menu.

In another embodiment, the moving means 40 may be omitted. Specifically, the exercise apparatus 30 can directly communicate with the wearable device 60 to obtain physiological information of the user. The fitness equipment 30 sends the acquired physiological information to the server 50, the server 50 generates a sports menu according to the received physiological information and transmits the sports menu back to the fitness equipment 30, and the fitness equipment 30 sets a sports program according to the sports menu.

Referring also to fig. 2, in the present embodiment, the exercise apparatus 30 includes, but is not limited to, a first memory 70, at least one first processor 80, a first wireless communication component 90, and one or more modules that can be stored in the first memory 70 and executed by the at least one first processor 80. And the above components are electrically connected.

The first memory 70 may be a memory of the exercise apparatus 30 itself, or may be an external memory, such as a Smart Media Card (Smart Media Card), a Secure Digital Card (Secure Digital Card), a flash memory Card (FlashCard), etc.

The first processor 80 may be a central processing unit, a microprocessor or other chip with data processing function.

The first wireless communication component 90 may be a WIFI module or a bluetooth module, and the first wireless communication component 90 is configured to transmit and receive wireless signals.

In this embodiment, the one or more modules, for example, include: a setting module 31 and a judging module 32. The modules referred to in the present invention refer to program segments capable of performing a specific function, and are more suitable than programs for describing the execution process of software in the exercise apparatus 30, and the detailed functions of the modules will be described in detail with reference to the flowchart of fig. 4.

Referring to fig. 3, in the present embodiment, the server 50 includes, but is not limited to, a second memory 72, at least one second processor 82, a second wireless communication component 92, and one or more modules stored in the second memory 72 and executed by the at least one second processor 82. And the above components are electrically connected.

The second storage 72 may be a memory of the server 50 itself, or may be an external storage, such as a Smart Media Card (Smart Media Card), a Secure Digital Card (Secure Digital Card), a flash memory Card (FlashCard), and so on.

The second processor 82 may be a central processing unit, a microprocessor, or other chip with data processing function.

The second wireless communication component 92 may be a WIFI module or a bluetooth module, and the second wireless communication component 92 is configured to transmit and receive wireless signals.

In this embodiment, the one or more modules, for example, include: a motion menu generation module 35. The modules referred to in the present invention refer to program segments capable of performing a specific function, and are more suitable than programs for describing the execution process of software in the server 50, and the detailed functions of the modules will be described in detail with reference to the flowchart of fig. 4.

Referring to fig. 4, a flow chart of a preferred embodiment of the control method of the fitness equipment of the present invention is shown. The order of the steps in the flow chart may be changed, and some steps may be omitted or combined according to different requirements.

In step S200, the first wireless communication component 90 receives the motion menu.

In this embodiment, the motion menu may be from the mobile device 40 or the server 50.

The motion menu may include at least one of a motion speed, a motion intensity, and a motion duration.

In one embodiment, the exercise apparatus 30 is a treadmill, the exercise speed may refer to a track rotation speed of the exercise apparatus 30, the exercise intensity may be a running grade of the user while the track runs, and the exercise duration may be a running duration set for the user at the exercise apparatus 30. In another embodiment, the exercise machine 30 is an exercise bike, and the exercise intensity may be the resistance of the wheels of the exercise machine 30.

For example, the motion menu is from the mobile device 40. The mobile device 40 communicates with the wearable device 60 to obtain physiological information of the user. The mobile device 40 sends the acquired physiological information to the server 50, and the motion menu generating module 35 generates a motion menu according to the received physiological information. The second wireless communication component 92 sends the motion menu to the mobile device 40. The mobile device 40, in turn, communicates with the first wireless communication component 90 of the exercise apparatus 30 to enable the exercise menu to be sent to the exercise apparatus 30.

For example, the motion menu is from the server 50. The exercise apparatus 30 can directly communicate with the wearable device 60 through the first wireless communication component 90 to obtain the physiological information of the user. The first wireless communication component 90 sends the acquired physiological information to the server 50, and the motion menu generating module 35 generates a motion menu according to the received physiological information. The second wireless communication component 92 sends the exercise menu to the first wireless communication component 90, so that the exercise machine 30 can set an exercise program according to the received exercise menu.

In an embodiment, the wearable device 60 may be one or more of a smart band, a smart watch, a smart garment, a smart shoe, and other wearable electronic devices. The wearable device 60 includes at least one sensor, such as a gravity sensor or a gyroscope sensor (not shown), for detecting a sleep state and/or a movement state of the user and generating a sleep record and/or a movement record of the user.

The physiological information is a sleep record and/or an exercise record of the user. The sleep record may include at least one of a sleep duration, a sleep quality, and a heartbeat frequency of the user. The sleep quality can be obtained by analyzing the historical sleep record, if the sleep duration of the user in the last few days is greater than a preset value, the sleep quality of the user is considered to be good, otherwise, the sleep quality is considered to be poor. The sleep duration may be calculated from the sleep state of the user. The sleep state may be a shallow sleep state or a deep sleep state. For example, when the user is sleeping and the wearable device senses that the user has a turning-over or other actions, it is determined that the user is in the shallow sleep state; and when the user does not have any action within a preset time period, judging that the user is in the parasomnia state. In an embodiment, the sleep duration may be the user parasomnia duration. In another embodiment, the sleep duration may be the user parasomnia duration plus a proportion of the user light sleep duration. The movement record may be a length of time of the movement of the user. When the user moves and the wearable device senses that the user has motion actions such as running and the like, judging that the user is in the fitness state; and when the user does not have sports actions such as running within a preset time period, judging that the user is in the rest state. The exercise duration may be the user fitness state duration.

In one embodiment, when the user needs to exercise, the user may actively establish a wireless connection with the exercise apparatus 30 that is available nearby via the mobile device 40. The exercise equipment 30 with the idle status can be defined as the exercise equipment 30 within a predetermined range from the mobile device 40 and working without establishing a connection with any electronic device. The preset range may be preset in the mobile device 40, and the preset range may be 1km, 2km, 3km, or the like.

In an embodiment, the server 50 stores a historical motion menu of the user, and the motion menu generation module 35 may further adjust the intensity of the motion menu according to the sleep state of the user and the historical motion menu. The intensity of the motion menu can be the speed of the motion speed, the height of the motion gradient and the length of the motion time. If the sleep state of the user is good and/or the intensity of the historical motion menu is high, the intensity of the motion menu can be improved; the intensity of the motion menu may be reduced if the user's sleep state is poor and/or the historical motion menu intensity is poor.

In step S201, the setting module 31 sets the exercise program of the exercise equipment 30 according to the exercise menu.

In one embodiment, the exercise apparatus 30 is in communication connection with the server 50 through the first wireless communication component 90 and the second wireless communication component 92, the exercise apparatus 30 can directly obtain the exercise menu from the server 50, and the setting module 31 can set the exercise program of the exercise apparatus according to the exercise menu.

In another embodiment, the mobile device 40 may be communicatively connected to the second wireless communication component 92 of the server 50, and the mobile device 40 may also be communicatively connected to the first wireless communication component 90 of the exercise apparatus 30. The mobile device 40 obtains the exercise menu from the server 50 and transmits the exercise menu to the exercise apparatus 30, and the setting module 31 may set an exercise program of the exercise apparatus 30 according to the exercise menu.

In step S202, the determining module 32 determines whether at least one starting signal is received, and starts the exercise apparatus 30 after receiving at least one starting signal.

In this embodiment, the wearable device 60 is a smart shoe, and the exercise apparatus 30 further includes at least one sensor (not shown) for detecting the exercise frequency of the user, such as a pressure sensor, a gravity sensor, etc. The movement frequency may be a step frequency. When the user starts to run or walk, the sensor module of the wearable device 60 or the sensor of the fitness equipment 30 senses the change of the exercise frequency of the user and sends out a starting signal, and the determining module 32 determines whether at least one starting signal is received, and starts the fitness equipment 30 after receiving at least one starting signal.

It is understood that the frequency of the user's movements may be varied and that such variations may be detected by the wearable device 60 or the exercise apparatus 30, for example, the wearable device 60 may be provided with a gravity sensor module or the exercise apparatus may be provided with a pressure sensor module. When the exercise device 30 is started and the user is exercising, the determining module 32 may determine the change of the exercise frequency of the user according to the data detected by the gravity sensor or the pressure sensor. The setting module 31 may adjust the intensity of the exercise menu of the exercise apparatus in real time according to the change of the exercise frequency of the user determined by the determining module 32 and reset the exercise program of the exercise apparatus 30. For example, when the determination module 32 determines that the pace frequency of the user is increasing, the setting module 31 may increase the exercise speed, increase the exercise slope, and/or increase the exercise time. When the determination module 32 determines that the user's pace frequency is slowed, the setup module 31 may slow down the exercise speed, decrease the exercise slope, and/or shorten the exercise time.

In step S203, the determining module 32 determines whether at least one stop signal is received, and turns off the exercise device 30 after receiving at least one stop signal.

When the user stops running or walking, the gravity sensor module of the wearable device 60 and/or the pressure sensor of the fitness equipment 30 sense that the movement frequency of the user changes and send a stop signal, and the determining module 32 determines whether at least one of the stop signals is received, and stops the fitness equipment 30 after receiving at least one of the stop signals.

When the start signal, stop signal, and motion frequency are from the sensor module of the wearable device 60, the determination module 32 may receive the start signal, stop signal, and motion frequency from the wearable device 60 through the first wireless communication component 90.

In this embodiment, the server 50 may further detect whether the user has a motion record within a preset time period through a detection module (not shown), and send a prompt signal when the user has no record within the preset time period. The preset time period may be a preset number of days, and the preset number of days may be 2 days, 3 days, 4 days, and the like. Specifically, the detection module can detect the number of exercise days of the user in the last period of time, compare the number of exercise days with a preset number of days, and send the prompt signal when the number of exercise days of the user in the last period of time is less than the preset number of days. In other embodiments, the preset time period may be consecutive days, which may be 2 days, 3 days, 4 days, etc. Specifically, the detection module may detect a motion record of the user in a recent period of time, and send the prompt signal when the number of consecutive days in which the user has not moved recently is greater than a preset number of days.

In one embodiment, the server 50 may send the prompt signal to the user's wearable device 60 or mobile device 40 through the second wireless communication component 92.

The fitness equipment and the control method thereof can automatically set the exercise program by combining the physiological state of the user, and improve the operation convenience and the intellectualization of the fitness equipment.

It will be apparent to those skilled in the art that other variations and modifications may be made in accordance with the invention and its spirit and scope in accordance with the practice of the invention disclosed herein.