CN111513698A - Heart rate data transmission method and intelligent wearable device - Google Patents

Abstract

The utility model relates to an intelligence wearing equipment field especially relates to a rhythm of heart conveying method and intelligent wearing equipment. The heart rate monitor acquires the original heart rate information of a user, and then sends the original heart rate information to the MCU of the intelligent wearable device, and the MCU analyzes the original heart rate information of the user to acquire real heart rate data of the user, so that MDSP can be omitted in the intelligent wearable device, the sending flow of the heart rate data of the user can be simplified, the energy consumption of the intelligent wearable device can be reduced, and the cruising ability of the intelligent wearable device is improved.

Description

Heart rate data transmission method and intelligent wearable device

Technical Field

The utility model relates to an intelligence wearing equipment field especially relates to a heart rate data transfer method and intelligent wearing equipment.

Background

In the related art, an MDSP (Modem Digital signal processor) is generally provided in a chip of the smart wearable device. Heart rate monitoring devices in intelligent wearing equipment (for example, intelligent watch) can send the raw data who gathers to MDSP after gathering user's heart rate information, then handles received data by MDSP, and the user heart rate data that obtains after will handling by MDSP sends to intelligent wearing equipment's CPU side again. However, when the CPU of the smart wearable device is in a sleep state, the MDSP needs to frequently wake up the CPU to transmit the heart rate data of the user, thereby increasing the energy consumption of the smart wearable device. And the power consumption of the MDSP is higher, so that the energy consumption of the intelligent wearable equipment can be further increased.

Disclosure of Invention

In order to solve at least one of the above technical problems, the present disclosure provides a heart rate data transmission method and an intelligent wearable device.

In one aspect, an embodiment of the present disclosure provides a method for transmitting heart rate data, where the method is applied to an intelligent wearable device, where the intelligent wearable device includes a heart rate monitor, an MCU, and a CPU, and the method includes:

the heart rate monitor acquires original heart rate information of a user;

the heart rate monitor sends the original heart rate information to the MCU;

the MCU analyzes the original heart rate information to acquire heart rate data of a user;

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU.

Optionally, the heart rate monitor is a heart rate sensor, and the heart rate sensor acquires the raw heart rate information through a PPG technique.

Optionally, after the user heart rate data is acquired, the MCU stores the user heart rate data in a FIFO memory.

Optionally, after the CPU enters the operating state from the sleep state, the MCU sends the heart rate data of the user to the CPU at preset time intervals.

Optionally, after the MCU acquires the user heart rate data, the MCU displays the user heart rate data on an LCD screen of the MCU side.

On the other hand, the embodiment of the present disclosure provides an intelligent wearable device, which includes a heart rate monitor, an MCU and a CPU;

the heart rate monitor is configured to acquire original heart rate information of a user and send the original heart rate information to the MCU;

the MCU is configured to parse the raw heart rate information to obtain user heart rate data;

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU.

Optionally, the heart rate monitor is a heart rate sensor, and the heart rate sensor acquires the raw heart rate information through a PPG technique.

Optionally, after the user heart rate data is acquired, the MCU stores the user heart rate data in a FIFO memory.

Optionally, after the CPU enters the operating state from the sleep state, the MCU sends the heart rate data of the user to the CPU at preset time intervals.

Optionally, after the MCU acquires the user heart rate data, the MCU displays the user heart rate data on an LCD screen of the MCU side.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects:

the heart rate monitor acquires the original heart rate information of a user, and then sends the original heart rate information to the MCU of the intelligent wearable device, and the MCU analyzes the original heart rate information of the user to acquire real heart rate data of the user, so that MDSP can be omitted in the intelligent wearable device, the sending flow of the heart rate data of the user can be simplified, the energy consumption of the intelligent wearable device can be reduced, and the cruising ability of the intelligent wearable device is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the disclosure and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the disclosure and together with the description serve to explain the principles of the disclosure.

Fig. 1 is a flow chart of a heart rate delivery method provided by a first embodiment of the present disclosure;

fig. 2 is a flow chart of a heart rate delivery method provided by a second embodiment of the present disclosure;

fig. 3 is a schematic view of an intelligent wearable device provided in a third embodiment of the present disclosure.

Detailed Description

The present disclosure will be described in further detail with reference to the drawings and embodiments. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not to be construed as limitations of the present disclosure. It should be further noted that, for the convenience of description, only the portions relevant to the present disclosure are shown in the drawings.

It should be noted that the embodiments and features of the embodiments in the present disclosure may be combined with each other without conflict. The present disclosure will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

A first embodiment of the present disclosure provides a method for transmitting heart rate data, as shown in fig. 1, the method is applied to an intelligent wearable device, such as an intelligent watch, an intelligent helmet, an intelligent ring, or the like, where the intelligent wearable device includes a heart rate monitor, an MCU (micro controller Unit), and a CPU (Central Processing Unit). The method comprises the following steps:

s101, the heart rate monitor acquires original heart rate information of a user.

S102, the heart rate monitor sends the acquired original heart rate information to the MCU of the intelligent wearable device.

S103, the MCU of the intelligent wearable device analyzes the received original heart rate information to obtain heart rate data of the user;

and S104, after the CPU of the intelligent wearable device enters a working state from a dormant state, the MCU sends heart rate data of the user to the CPU.

Optionally, the heart rate monitor is a heart rate sensor, and the heart rate sensor acquires raw heart rate information of the user through a PPG technique.

Optionally, after the user heart rate data is acquired, the MCU of the smart wearable device stores the user heart rate data in the FIFO memory.

Optionally, after the CPU of the intelligent wearable device enters a working state from a sleep state, the MCU of the intelligent wearable device sends the heart rate data of the user to the CPU of the intelligent wearable device every preset time period.

Optionally, after the MCU of the intelligent wearable device acquires the heart rate data of the user, the MCU displays the heart rate data of the user on the LCD screen of the MCU side.

In this embodiment, the heart rate monitor acquires user's original heart rate information after, with this original heart rate information transmission to intelligent wearing equipment's MCU, analyze user's original heart rate information by this MCU, thereby acquire real user heart rate data, and carry out the buffer memory with the real user heart rate data who acquires, thereby can omit MDSP in intelligent wearing equipment, user's heart rate data's transmission flow can be simplified, and also can reduce intelligent wearing equipment's energy consumption, improve intelligent wearing equipment's duration.

A second embodiment of the present disclosure provides a method for transmitting heart rate data, as shown in fig. 2, the method is applied to an intelligent wearable device, such as an intelligent watch, an intelligent helmet, or an intelligent ring, where the intelligent wearable device includes a heart rate monitor, an MCU, and a CPU. In one possible implementation, the intelligent wearable device supports dual system operation. For example, the intelligent wearable device supports the simultaneous operation of an intelligent operating system on the CPU side and a microkernel system on the MCU side. The method comprises the following steps:

s201, the heart rate monitor acquires original heart rate information of a user.

Bioelectrical changes in the heart itself are typically reflected on the surface of the user's body by conductive tissue and fluids surrounding the heart, causing regular electrical signal changes to occur at various parts of the user's body during each cardiac cycle. Therefore, when the user uses the intelligent wearable device, the heart rate monitor arranged in the intelligent wearable device can acquire the original heart rate information of the user according to the electric signal change generated by the corresponding body part of the user, or the original heart rate information of the user can be considered to be the electric signal information of the body part of the user contacting with the intelligent wearable device.

In one possible implementation, the heart rate monitor may be a heart rate sensor that may acquire raw heart rate information of the user in real time through a PPG (Photo pulse graphics) technique.

S202, the heart rate monitor sends the acquired original heart rate information to the MCU of the intelligent wearable device.

S203, the MCU of the intelligent wearable device analyzes the received original heart rate information to obtain heart rate data of the user.

Since the heart rate monitor obtains the original heart rate information of the user according to the electrical signal variation of the body part of the user contacting with the heart rate monitor, the heart rate monitor inevitably acquires some impurity data, or the data acquired by the heart rate monitor may deviate from the actual data. Therefore, after the heart rate monitor acquires the original heart rate information of the user, the acquired original heart rate information of the user can be sent to the MCU of the intelligent wearable device, so that the original heart rate information of the user is analyzed through the MCU, and real heart rate data of the user is acquired.

In one possible implementation, after receiving the original heart rate information of the user, the MCU may invoke a heart rate parsing algorithm to parse the original heart rate information. For example, the heart rate analysis algorithm may determine whether the frequency of the original heart rate data is within a preset heart rate frequency interval, and when a part of data in the original heart rate data is within the preset heart rate frequency interval, the part of data may be used as the heart rate data of the user, and other data that is not within the preset heart rate frequency interval may be discarded as the impurity data. Wherein, it can be set up before intelligent wearing equipment leaves the factory by technical staff to predetermine heart rate frequency interval, perhaps also can be set up according to the needs of oneself by intelligent wearing equipment's user.

In a possible implementation manner, the MCU side of the intelligent wearable device may provide a data interface for the third-party application, so that the third-party application can acquire the original heart rate information or the analyzed heart rate data of the user. For example, the MCU side of the smart wearable device may provide a data interface for a third party application such as Google file or Strava.

And S204, the MCU of the intelligent wearable device stores the acquired heart rate data of the user.

After the MCU of the intelligent wearable device acquires real user heart rate data by analyzing received original heart rate information, the user heart rate data can be stored, so that when the application on the CPU side of the intelligent wearable device needs to use the user heart rate data, the user heart rate data can be directly called from the MCU.

In a possible implementation manner, the MCU may store the acquired user heart rate data in a FIFO (First input First Output) memory.

In a possible implementation mode, after the MCU of the intelligent wearable device acquires the heart rate data of the user, the user data can be displayed on the LCD display screen of the MCU side in a digital form, so that the user of the intelligent wearable device can check the heart rate data when the CPU of the intelligent wearable device is not awakened. In this implementation, the smart wearable device may include an LCD display screen and an OLED display screen. The intelligent operating system on the CPU side can control the OLED display screen, the micro-kernel system on the MCU side can control the LCD display screen, and when the CPU of the intelligent wearable device is in a dormant state or a shutdown state, the micro-kernel system on the MCU side can also control the OLED display screen. OLED display screen and LCD display screen of intelligence wearing equipment can the stack setting. For example, the OLED display may be disposed on an upper layer of the LCD display, or the LCD display may be disposed on an upper layer of the OLED display. After the CPU of the intelligent wearable device acquires the heart rate data of the user, the heart rate data of the user can be displayed on the OLED display screen in a digital mode.

In one possible implementation, the user heart rate data may be displayed in digital form in pen-segments or dot-matrix on an LCD screen on the MCU side or an OLED screen on the CPU side.

S205, after the CPU of the intelligent wearable device enters a working state from a dormant state, the MCU of the intelligent wearable device sends the heart rate data of the user to the CPU.

After the CPU of intelligent wearing equipment entered operating condition, for example after the CPU of intelligent wearing equipment was awaken up by the user of intelligent wearing equipment, the MCU of intelligent wearing equipment can send the user heart rate data of cache to CPU to the application of CPU side uses this user heart rate data. And when the CPU of intelligent wearing equipment was in the dormancy state, MCU need not send user's rhythm of the heart data to CPU, need not awaken up CPU promptly to can avoid awakening up CPU frequently, avoid increasing intelligent wearing equipment's energy consumption.

In a possible implementation manner, after the CPU of the intelligent wearable device enters a working state, the MCU may send the heart rate data of the user to the CPU at intervals of a preset time period. For example, the MCU may send user heart rate data to the CPU every 2min or 5 min. In this implementation manner, it may also be considered that the MCU may transmit the user heart rate data to the CPU after the storage time of the user heart rate data in the MCU satisfies the preset time period.

It can be understood that the user heart rate data sent by the MCU to the CPU or the user heart rate data called by the CPU from the MCU is obtained by the MCU analyzing the original heart rate information of the user obtained by the heart rate monitor within the latest preset time period (for example, the latest 2min or 5 min). It should be noted that the preset time period and the preset time period may be set by a technician before the intelligent wearable device leaves a factory, or may also be set by a user of the intelligent wearable device according to a need of the user, and the values of the preset time period and the preset time period may be the same or different. When the MCU sends the heart rate data of the user to the CPU, the data can be sent in a centralized manner by using a locking mechanism.

By caching the heart rate data of the user in the MCU, the application on the CPU side calls the heart rate data of the user from the MCU when the heart rate data of the user is needed to be used, or after the CPU enters a working state from a dormant state, the MCU actively sends the heart rate data of the user to the CPU at intervals of a preset time period, so that the data can be prevented from being sent to the CPU every second, the CPU is prevented from being awakened uninterruptedly, and the power consumption of the CPU can be reduced.

In this embodiment, the heart rate monitor acquires user's original heart rate information after, with this original heart rate information transmission to intelligent wearing equipment's MCU, analyze user's original heart rate information by this MCU, thereby acquire real user heart rate data, and carry out the buffer memory with the real user heart rate data who acquires, thereby can omit MDSP in intelligent wearing equipment, user's heart rate data's transmission flow can be simplified, and also can reduce intelligent wearing equipment's energy consumption, improve intelligent wearing equipment's duration. Simultaneously, user's rhythm of the heart information that the rhythm of the heart monitor was gathered is received through the MCU by intelligent wearing equipment to can still can collect user's rhythm of the heart information when the CPU of intelligent wearing equipment is in dormant state or power off state, avoid the collection of being interrupted to user's rhythm of the heart information.

A third embodiment of the present disclosure provides a smart wearable device, as shown in fig. 3, the smart wearable device 300 may be a smart watch, a smart helmet, a smart ring, or the like. The smart wearable device 300 includes a heart rate monitor 301, an MCU302, and a CPU 303. Wherein the content of the first and second substances,

the heart rate monitor 301 is configured to acquire original heart rate information of a user and transmit the acquired original heart rate information to the MCU 302;

the MCU302 is configured to parse the received raw heart rate information to obtain user heart rate data;

after the CPU303 enters the operating state from the sleep state, the MCU302 sends the user heart rate data to the CPU 303.

In one possible implementation, the heart rate monitor 301 is a heart rate sensor that acquires raw heart rate information of the user by PPG technology.

In one possible implementation, after the user heart rate data is acquired, the MCU302 stores the user heart rate data to a FIFO memory.

In one possible implementation, after the CPU303 enters the operating state from the sleep state, the MCU302 sends the user heart rate data to the CPU303 every preset time period.

In one possible implementation, after the MCU302 acquires the user heart rate data, the MCU302 displays the user heart rate data on an LCD screen on the MCU302 side.

In this embodiment, the heart rate monitor acquires user's original heart rate information after, with this original heart rate information transmission to intelligent wearing equipment's MCU, analyze user's original heart rate information by this MCU, thereby acquire real user heart rate data, and carry out the buffer memory with the real user heart rate data who acquires, thereby can omit MDSP in intelligent wearing equipment, user's heart rate data's transmission flow can be simplified, and also can reduce intelligent wearing equipment's energy consumption, improve intelligent wearing equipment's duration.

It should be noted that the intelligent wearable device and the heart rate data transmission method provided by the above embodiment belong to the same concept, and specific implementation processes thereof are described in the method embodiment and are not described herein again.

In the description herein, reference to the description of the terms "one embodiment/mode," "some embodiments/modes," "example," "specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment/mode or example is included in at least one embodiment/mode or example of the application. In this specification, the schematic representations of the terms used above are not necessarily intended to be the same embodiment/mode or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments/modes or examples. Furthermore, the various embodiments/aspects or examples and features of the various embodiments/aspects or examples described in this specification can be combined and combined by one skilled in the art without conflicting therewith.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

It will be understood by those skilled in the art that the foregoing embodiments are merely for clarity of illustration of the disclosure and are not intended to limit the scope of the disclosure. Other variations or modifications may occur to those skilled in the art, based on the foregoing disclosure, and are still within the scope of the present disclosure.

Claims (10)

1. A heart rate data transmission method is applied to intelligent wearable equipment, the intelligent wearable equipment comprises a heart rate monitor, an MCU and a CPU, and the method comprises the following steps:

the heart rate monitor acquires original heart rate information of a user;

the heart rate monitor sends the original heart rate information to the MCU;

the MCU analyzes the original heart rate information to acquire heart rate data of a user;

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU.

2. The heart rate data transmission method of claim 1, wherein the heart rate monitor is a heart rate sensor that acquires the raw heart rate information via PPG techniques.

3. The method of claim 1 or 2, wherein the MCU stores the user heart rate data to a FIFO memory after the user heart rate data is acquired.

4. Heart rate data transmission method according to claim 1 or 2,

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU at intervals of a preset time period.

5. The method for transmitting heart rate data according to claim 1 or 2, wherein after the MCU acquires the user heart rate data, the MCU displays the user heart rate data on an LCD screen on the MCU side.

6. The intelligent wearable device is characterized by comprising a heart rate monitor, an MCU (microprogrammed control unit) and a CPU (central processing unit);

the heart rate monitor is configured to acquire original heart rate information of a user and send the original heart rate information to the MCU;

the MCU is configured to parse the raw heart rate information to obtain user heart rate data;

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU.

7. The smart wearable device of claim 6, wherein the heart rate monitor is a heart rate sensor that acquires the raw heart rate information via PPG technology.

8. The intelligent wearable device according to claim 6 or 7, wherein after the user heart rate data is acquired, the MCU stores the user heart rate data to a FIFO memory.

9. The smart wearable device of claim 6 or 7,

and after the CPU enters a working state from a dormant state, the MCU sends the heart rate data of the user to the CPU at intervals of a preset time period.

10. The intelligent wearable device according to claim 6 or 7, wherein after the MCU acquires the user heart rate data, the MCU displays the user heart rate data on an LCD screen on the MCU side.

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