TWI729150B - Smart earphone, smart earphone system, and physiological-information indicating method used in earphone - Google Patents

Abstract

A smart earphone includes a body, a control module located at the body, a pulsation measurement module, a speaker module, and a communication module. The pulsation measurement module is electrically connected to the control module, near the skin of a user to receive a pulsation sound, and generates a pulsation signal according to the pulsation sound. The speaker module is electrically connected to the control module. The speaker module generates a normal sound according to a sound signal or generates a warning sound according to a warning signal. The communication module is electrically connected to the control module and wirelessly connected to a mobile device. The communication module receives the sound signal sent by the mobile device and transmits the sound signal to the speaker module via the control module.

Description

Smart earphone, smart earphone system and physiological information prompt method for earphone

The present invention relates to an earphone, especially a smart earphone and a smart earphone system.

With the rise of health awareness, aerobic exercises such as jogging and cycling are becoming more and more popular. They not only directly benefit heart function and vital capacity, but also release "endorphins" to enhance thinking ability. Improve short-term memory and spark creativity.

However, most people are unable to grasp the physical load of jogging and other exercises. It often exceeds the range of physical capacity and causes heat failure, myocardial infarction, etc., and what is more, causes the heart to be unable to load, arrhythmia, and insufficient blood oxygen. And deaths from shock are not uncommon.

Therefore, establish a fixed and continuous exercise habit, and when the body shows signs of exceeding the physical burden, the exercise intensity should be reduced to avoid the aforementioned dangers. However, it is easy for ordinary people to ignore the signs of exceeding physical burden, or do not know that their body has signs of exceeding physical burden. Therefore, how to judge the appropriate amount of exercise and avoid exceeding the physical burden is a very important topic for most people.

In view of this, an embodiment of the present invention provides a smart headset, including: a headset body; a control module located in the headset body; a pulsation measurement module electrically connected to the control module and close to the skin of a user And receiving a pulsating sound, according to the pulsating sound, a Pulse signal; a sound module, electrically connected to the control module, generating a sound according to a sound signal or generating a warning tone according to a warning sound signal; and a communication module, electrically connected to the control module, wireless connection A mobile device receives the sound signal transmitted by the mobile device and transmits it to the sound module through the control module.

Another embodiment of the present invention provides a smart headset system, including: a cloud host; a mobile device connected to the cloud host; and a smart headset headset as described above, connected to the mobile device or the cloud through the communication module Host, the smart earphone transmits a measurement information to the mobile device or the cloud host, and the measurement information at least includes the pulsation signal.

Another embodiment of the present invention provides a physiological information prompting method for earphones, which includes: receiving a pulsating sound with a pulsation measurement module close to the skin of a user; generating a pulsation signal according to the pulsating sound; and responding to the pulsation signal When it is abnormal, a warning sound signal is generated; and a sounding module is used to generate a warning sound according to the warning sound signal.

When the user wears the smart earphone proposed in an embodiment of the present invention, the user’s pulsating sound can be received. Therefore, when the user is exercising, he can listen to his favorite music and measure the user’s pulsation during exercise. It also provides voice notifications based on the pulse information, so that users can know their physical status at any time, without the need to use mobile phones or sports bracelets to inquire. Furthermore, when performing weight loss exercises, users can learn the pulse information through smart earphones and smart earphone systems, so as to achieve the most suitable heartbeat per minute for burning fat, and then get the best weight loss effect.

1: Smart headset

10: Headphone body

11: Control module

12: Pulsation measurement module

13: Vibrator

14: Sound module

15: Communication module

16: Body temperature detection module

161: Infrared emission module

162: Infrared receiver module

17: Gravity sensor

18: Barometer

19: Charging module

2: mobile device

3: Cloud host

5: Storage unit

51: Charger

[Figure 1] is a schematic diagram (1) of the appearance of the first embodiment of the present invention.

[Figure 2] is a schematic diagram (1) of the use of the first embodiment of the present invention.

[Fig. 3] is a schematic diagram of charging of the first embodiment of the present invention.

[Figure 4] is a schematic diagram (2) of the appearance of the first embodiment of the present invention.

[Figure 5] is a schematic diagram (2) of the use of the first embodiment of the present invention.

[Figure 6] is a functional block diagram (1) of the first embodiment of the present invention.

[Figure 7] is a functional block diagram (2) of the first embodiment of the present invention.

[Figure 8] is a functional block diagram of the second embodiment of the present invention.

[Figure 9] is a functional block diagram of the third embodiment of the present invention.

[Fig. 10] is a functional block diagram of the fourth embodiment of the present invention.

[Figure 11] is a schematic diagram of the smart headset system of the present invention.

Please refer to FIGS. 1 to 6 at the same time, which are schematic diagrams of the smart headset according to the first embodiment of the present invention. The smart headset 1 of the first embodiment of the present invention includes: a headset body 10, a control module 11, a pulsation measurement module 12, a sounding module 14, and a communication module 15.

The earphone body 10 can be made of materials such as plastic, ceramic or carbon fiber. A part of it can be inserted into the ear canal of the user, and a part can be hung on the ear of the user, or a part of it can be put on the neck of the user, or A part of it can be close to the temple of the user (please refer to Figures 2 and 5), and the place close to the temple of the user includes the place where it is directly attached to the temple. In general, the earphone body 10 may be, for example, an ear-hook earphone (please refer to FIGS. 1 and 2), a headset, a bone conduction earphone (please refer to FIGS. 4 and 5), etc., but not the same. Is limited.

The control module 11 is located on the earphone body 10 for processing various signals.

The pulsation measurement module 12 is electrically connected to the control module 11 and is close to the skin of the user to receive the pulsation sound of the user, and can generate a pulsation signal according to the pulsation sound. Here, pulsation The measurement module 12 may be a microphone, for example, it may be a directional microphone, as long as it can receive small sounds and has a certain noise reduction function, or the pulsation measurement module 12 may include a microphone and a noise reduction module, In order to achieve a good radio effect. In this embodiment, the pulsation measurement module 12 can be arranged on the earphone body 10 and located on the side of the opening of the ear canal. Therefore, it can be close to the temple of the user to obtain the pulsation sound of the cerebral artery in the temple. This position is only an example, not a limitation, as long as the pulsation measurement module 12 can obtain the pulsation sound. For example, it may be set at the position of the earplug for the user to put in the ear canal, so as to contact the user. Pulsating sound from the ear canal.

The sound module 14 is electrically connected to the control module 11, and generates a sound according to the sound signal or generates a warning sound according to the warning sound signal. Here, the sound module can be various types of speakers, such as electromagnetic, electrodynamic, piezoelectric, etc., but not limited to this.

The communication module 15 is electrically connected to the control module 11, is connected to the mobile device 2 wirelessly, and receives the sound signal transmitted by the mobile device 2 and transmits it to the sound generating module 14 via the control module 11. Here, the mobile device 2 is a portable electronic device for the user, such as a mobile phone or a wearable electronic device, which can be connected to the communication module 15 with standard communication protocols such as Bluetooth, ZigBee, Wi-Fi, etc. However, the foregoing description is only For example, and not limited to this, a mobile phone or a wearable electronic device can be connected to the communication module 15 with other standard communication protocols or non-standard communication protocols.

In an implementation aspect, the control module 11 can generate different sound signals according to different pulsation signals, generate a warning sound signal when the pulsation signal is abnormal, and transmit different sound signals or warning sound signals to the sound module 14. This means that the judgment of whether the pulsation signal is abnormal is done by the smart headset 1 side; in another implementation mode, the communication module 15 continuously transmits the pulsation signal to the mobile device 2, and the mobile device 2 can generate different pulse signals according to different pulsation signals. Sound signal, and generate a warning audio signal when the pulsation signal is abnormal, the control module 11 does not receive it through the communication module 15 The same audio signal or warning audio signal is sent to the sound module 14, which means that the mobile device 2 determines whether the pulsation signal is abnormal.

If the user is 40 years old, 180 heartbeats per minute is the maximum pulse; when the user exercises, such as jogging, he can wear the smart earphone 1 to listen to the music played by the mobile device 2 (the sound module 14 generates sound according to the sound signal ), the user’s heartbeat is 90 times, which has reached 50% of the maximum pulsation. At this time, the exercise intensity is slightly insufficient. Therefore, the mobile device 2 (or the control module 11) generates a sound signal of "speed up again". The sound module 14 generates the sound "can be accelerated", and the user listens to music while jogging, and can directly receive a reminder notification of "can be accelerated", which means that the sound module generates sound (music) At the same time, a warning sound (reminder notification that can be accelerated) is generated; when the user speeds up, his heartbeat reaches 126 times, which has reached 70% of the maximum pulse, which is the most suitable heartbeat per minute (BPM) for burning fat Therefore, the mobile device 2 (or the control module 11) generates a sound signal of "the optimal state is reached, continue to maintain", and the sound module 14 generates a sound of "the optimal state is reached, continue to maintain", which means The user listens to music while jogging, and can directly receive the reminder notification of "has reached the best condition, continue to maintain", without having to check the mobile phone or sports bracelet, so it will not change or disrupt the rhythm of the exercise at the time. Only need to maintain the current pace and continue jogging. But if the user continues to speed up his pace, his heartbeat reaches 180 times, which is the maximum pulse. As mentioned above, the mobile device 2 (or the control module 11) will generate a sound signal of "too fast, slow down". The sound module 14 generates a "too fast, slow down" sound to remind the user to reduce the intensity of exercise and prevent exercise injury or danger.

The voice reminder in the foregoing description is only an example, and it is not limited to this. The reminder method may be to change the rhythm of the music that the user listens to, for example, to speed up the music rhythm to remind the user to increase the exercise intensity; or the reminder The way may be a specific sound, ringtone, etc.

Please refer to FIG. 3, which is a schematic diagram of charging according to the first embodiment of the present invention. In this embodiment, the smart earphone 1 is provided with a charging module 19 on the earphone body 10 to provide power required by each component during operation. Here, the charging module 19 includes a battery and a charging terminal. The battery is located in the earphone body 10, and the charging terminal is exposed from the earphone body 10. When the smart earphone 1 is stored in the storage unit 5 with the charger 51, the charging module 19 The charging terminal is connected to the terminal of the charger 51 for charging. Therefore, when the user stores the smart earphone 1, it will be charged, and the smart earphone 1 can be used immediately after taking out the smart earphone 1 from the storage unit 5, which is quite convenient.

Please refer to FIG. 7, which is a functional block diagram (2) of the first embodiment of the present invention. In another implementation aspect, the smart earphone 1 of the first embodiment of the present invention further includes: a vibrator 13, electrically connected to the control module 11, which can be arranged on the earphone body 10 and located on the side of the opening of the ear canal , Or can be set at the position of the earplug for the user to put in the ear canal. The control module 11 can generate a vibration signal when the pulse signal is abnormal and send it to the vibrator 13. At this time, the vibrator 13 vibrates according to the vibration signal to remind the user that the exercise intensity is too strong. In addition, the communication module 15 may transmit a pulse signal to the mobile device 2. The mobile device 2 generates a vibration signal when the pulse signal is abnormal. The control module 11 receives the vibration signal through the communication module 15 and transmits it to the vibrator 13, so that The vibrator 13 vibrates to remind the user that the exercise intensity is too strong. Furthermore, the control module 11 or the mobile device 2 can generate different vibration signals according to different pulsation signals, which are the same as the description of the aforementioned different sound signals, and will not be repeated here.

Please refer to FIG. 8, which is a schematic diagram of a smart headset according to a second embodiment of the present invention. The difference between the second embodiment of the present invention and the first embodiment is that the smart headset 1 of this embodiment further includes a body temperature detection module 16.

In this embodiment, the body temperature detection module 16 is electrically connected to the control module 11, which can be installed on the earphone body 10 on the side of the opening of the ear canal, or can be installed at the earplug position for the user Place in the ear canal. The body temperature detection module 16 detects the body temperature of the user to generate a body temperature signal, which is sent to the mobile device 2 via the communication module 15 and the mobile device 2 continuously records the body temperature signal, and generates a body temperature abnormality notification when the body temperature signal is abnormal. Among them, the abnormal body temperature notification can be displayed on the screen of the mobile device 2, or be reminded by sound (mobile device 2 or sound module 14), or sent to other monitoring devices, such as the mobile phone of the user’s family, to let other family members It is known that the user's body temperature is abnormal.

Here, the body temperature detecting module 16 can be composed of an infrared emitting module 161 and an infrared receiving module 162, that is, infrared rays can achieve the purpose of body temperature detection. In addition, according to the reflected light, it can be judged whether it is inserted into the ear. The control module 11 judges that the user wears the smart earphone 1 according to the detection result of the body temperature detection module 16, generates an activation signal and sends it to the pulse measurement module 12 to activate The pulsation measurement module 12 starts to receive the pulsation sound, or the mobile device 2 determines that the user wears the smart headset 1 according to the detection result of the body temperature detection module 16, and generates an activation signal, and the control module 11 receives the activation via the communication module 15 The signal is sent to the pulsation measurement module 12 to activate the pulsation measurement module 12 to start receiving the pulsation sound. Furthermore, the body temperature detection module 16 measures the oxygen content of the blood in the blood vessel by the reflection of infrared rays, so as to achieve the purpose of heartbeat detection.

Novice parents can wear the smart earphone 1 on the baby to continuously monitor the baby’s body temperature through the smart earphone 1. In addition to continuously recording the body temperature, the mobile device 2 can generate different sound signals based on time, body temperature and other information, allowing The little baby hears different music. When a baby has a fever at night, the mobile device 2 will generate a notice of abnormal body temperature. For example, when a sound occurs, the novice parent immediately knows that the baby is in a fever state, and can immediately grasp the baby’s body temperature change and solve the conventional knowledge. The hands first detect whether the baby has overheated, and then use the ear thermometer to measure the unscientific and non-immediate problems.

Please refer to FIG. 9, which is a schematic diagram of a smart headset according to a third embodiment of the present invention. The difference between the third embodiment of the present invention and the previous two embodiments is that the smart headset 1 of this embodiment further includes a gravity sensor 17.

The gravity sensor 17, which is electrically connected to the control module 11, can be arranged on the earphone body 10 and located on the side of the opening of the ear canal, or can be arranged at the position of the earplug for the user to put into the ear canal. The gravity sensor 17 generates the gravity detection result and transmits it to the mobile device 2 via the communication module 15. The mobile device 2 calculates the movement result according to the gravity detection result, where the movement result can be, for example, walking, jogging, or brisk walking.

The mobile device 2 can send the exercise result to an electronic device (not shown). For example, if an elderly person puts on the smart earphone 1 to listen to music and accidentally falls, the mobile device 2 calculates the exercise result based on the gravity detection result, that is, the elderly person falls down. SMS or e-mail or communication software sends "falling" messages to other family members' mobile phones to let the family members know that the elderly at home have fallen down the first time.

When the user performs exercises such as walking or jogging, the mobile device 2 calculates information such as step count, distance, calories burned, etc. according to the gravity detection result, and generates an exercise result audio signal according to the aforementioned exercise result, and the control module 11 uses the communication module 15 Receive the exercise result sound signal and send it to the sound module 14, so that the sound module 14 can generate exercise result notifications based on the exercise result sound signal, such as the number of steps taken, distance traveled, calories consumed, etc., so that the user can Effectively grasp the effectiveness of the current exercise.

In another implementation aspect, when the control module 11 determines that the user is in a motion state based on the gravity detection result, it generates an activation signal and sends it to the pulsation measurement module 12 to activate it. The pulsation measurement module 12 starts to receive the pulsation sound, or the mobile device 2 generates an activation signal when it determines that the user is in motion based on the result of gravity detection, and the control module 11 receives the activation signal through the communication module 15 and sends it to the pulsation measurement module Group 12, to start the pulsation measurement module 12 to start receiving pulsation sounds. In other words, when the user wears the smart headset 1, the gravity detection result of the gravity sensor 17 can be used to determine whether the user is in a static state (such as sitting or lying down listening to music) or in an exercise state. When it is in an exercise state, the pulsation measurement module 12 starts to receive the pulsation sound, which not only achieves the function of automatically starting the pulsation measurement, but also effectively achieves the effect of saving power.

In addition, when the mobile device 2 determines that the user is in motion based on the gravity detection result generated by the gravity sensor 17, the application of the mobile device 2 can be automatically activated, and the application message sound signal is generated according to the running result of the application. The control module 11 receives the application program message sound signal via the communication module 15 and transmits it to the sound module 14 so that the sound module 14 generates the application program message sound according to the application program message sound signal. For example, when the mobile device 2 determines that the user is in motion based on the gravity detection result generated by the gravity sensor 17, the timer program of the mobile device 2 can be automatically activated to start calculating the user's exercise time. The user’s default value is reached. For example, when the exercise reaches one hour, the timer program will generate an application message sound signal. The sound module 14 generates a notification that the exercise time has reached one hour according to the application message sound signal, so that the user is effective Take control of exercise time without delaying other schedules. In addition, the application may be a weather program that provides weather notifications; or the application may be a clock program that provides time notification; the foregoing description of the application is only an example, and is not limited to this.

Please refer to FIG. 10, which is a schematic diagram of a smart headset according to a fourth embodiment of the present invention. The difference between the fourth embodiment of the present invention and the first three embodiments is that the smart headset 1 of this embodiment further includes a barometer 18.

The barometer 18 is electrically connected to the control module 11 and can be installed on the earphone body 10 and located on the side of the opening of the ear canal. The barometer 18 detects the air pressure state and generates an air pressure state signal. The mobile device 2 calculates the exercise result according to the aforementioned gravity detection result and the air pressure state signal, and sets the abnormal value condition of the pulsation signal according to the exercise result. For example, the barometer 18 detects the air pressure state to know the altitude of the user's location. Generally speaking, the air pressure state can be used to determine the altitude of the current mountaineering position when climbing. Since the physical strength consumed by walking on flat ground and climbing and climbing is completely different, the barometer 18 can grasp the change of altitude to learn more accurate exercise environment and conditions, and the mobile device 2 can calculate the exercise result more accurately, that is, to judge. As soon as the user is in a mountaineering state and the height of the location, the abnormal value condition of the pulse signal can be set according to the exercise result to remind the user to maintain a proper exercise intensity to prevent sports injury or danger.

Please also refer to FIG. 11, which is a schematic diagram of the smart headset system of the present invention. The smart earphone system of the present invention includes: the smart earphone 1, the mobile device 2 and the cloud host 3 of the foregoing embodiments. Among them, the mobile device 2 receives the measurement information sent by the smart headset 1 and sends it to the cloud host 3. The measurement information includes at least a pulse signal; here, the measurement information may also include body temperature signals, exercise results calculated by the mobile device 2, Information such as warning audio signals or fall notifications. Here, the measurement information is only an example.

After the aforementioned measurement information is stored in the cloud host 3, the user can use the mobile device 2 to connect to the cloud host 3 to query the measurement information at any time, and the cloud host 3 can provide users with tailor-made suggestions based on the measurement information. Send to the mobile device 2 to let the user know.

Furthermore, in another implementation aspect, the smart headset 1 can be connected to the cloud host 3 via the communication module 15 through 3G, 4G, and other communication protocols, but it is not limited to this. In this way, the measurement information of the smart headset 1 can be directly transmitted to the cloud host 3 and can receive feedback from the cloud host 3, such as but not limited to the warning audio signal described in the foregoing embodiment.

Another embodiment of the present invention provides a physiological information prompt method for earphones, which can be mainly used for the smart earphone 1 of the foregoing embodiment, but is not limited to this. The physiological information prompt method for earphones includes: Step 101: Use the pulsation measurement module 12 to approach the skin of the user to receive the pulsation sound; Step 102: Generate a pulsation signal according to the pulsation sound; Step 103: Generate when the pulsation signal is abnormal A warning sound signal; and step 104: generating a warning sound with the sound module 14 according to the warning sound signal.

As mentioned above, in an implementation aspect, the control module 11 can generate different sound signals according to different pulsation signals, generate a warning audio signal when the pulsation signal is abnormal, and send different sound signals or warning audio signals to The sound module 14 means that the judgment of whether the pulsation signal is abnormal is done by the smart headset 1 side; in another implementation mode, the communication module 15 continuously transmits the pulsation signal to the mobile device 2, and the mobile device 2 can be based on different The pulsation signal generates different sound signals, and when the pulsation signal is abnormal, a warning sound signal is generated. The control module 11 receives different sound signals or warning sound signals through the communication module 15 and sends them to the sound module 14, which means to determine the pulsation Whether the signal is abnormal is completed by the mobile device 2. In addition, in another implementation aspect, the cloud host 3 can replace the mobile device 2, which means that the communication module 15 continuously transmits a pulse signal to the cloud host 3. The cloud host 3 can generate different sound signals according to different pulse signals, and Pulsation signal When it is abnormal, a warning audio signal is generated. The control module 11 receives different sound signals or warning audio signals via the communication module 15 and transmits them to the sounding module 14, which means that the judgment of whether the pulsation signal is abnormal is completed by the cloud host 3. The other content is the same as the foregoing embodiment, and will not be repeated here.

In an implementation aspect, after the step of generating the warning audio signal, it further includes: generating a vibration with the vibrator 13 according to the warning audio signal. As mentioned above, the vibrator 13 generates vibration according to the vibration signal to remind the user, which will not be repeated here.

In one implementation aspect, when the pulsation measurement module 12 is used to approach the skin of the user, the step further includes: generating a gravity detection result with the gravity sensor 17; and calculating the exercise result according to the gravity detection result.

As mentioned above, the exercise result can be walking, jogging or brisk walking, etc., and can be used for fall detection of the elderly. In addition, the exercise result sound signal can also be generated based on the aforementioned exercise result. The content of this embodiment is the same as the aforementioned The description of the embodiments will not be repeated here.

In an implementation aspect, after the step of calculating the exercise result, it further includes: generating an activation signal when judging that the user is in an exercise state according to the gravity detection result; and driving the pulsation measurement module 12 to start receiving the pulsation sound according to the activation signal.

As mentioned earlier, when the user wears the smart headset 1, the gravity detection result of the gravity sensor 17 can be used to determine whether the user is in a static state (such as sitting or lying down listening to music) or in an exercise state. The pulsation measurement module 12 is started after determining that it is in a motion state to start receiving the pulsation sound, which will not be repeated here.

In an implementation aspect, the step of calculating the exercise result further includes: Detect the air pressure state to generate the air pressure state signal; and calculate the exercise result based on the gravity detection result and the air pressure state signal.

As mentioned above, the altitude of the user’s location can be obtained by detecting the air pressure state by the barometer 18, and the change in altitude can be grasped to learn more accurate exercise environment and conditions. The content of this embodiment is the same as the previous embodiment. The explanation of the example will not be repeated here.

In an implementation aspect, when the pulsation measurement module 12 is used to approach the skin of the user, the step further includes: detecting the body temperature of the user to generate a body temperature signal; recording the body temperature signal; and generating when the body temperature signal is abnormal Notification of abnormal body temperature.

As mentioned above, the body temperature signal is generated by detecting the body temperature of the user through the body temperature detecting module 16, the content of which is the same as the description of the foregoing embodiment, and will not be repeated here.

In summary, when the user wears the smart earphone proposed in an embodiment of the present invention, the user’s pulsating sound can be received. Therefore, when the user is exercising, he can listen to his favorite music and measure the user’s presence at the same time. The pulsation of the exercise status is provided with voice notifications based on the pulsation information, so that users can know their physical status at any time, without the need to inquire with a mobile phone or a sports bracelet. Furthermore, when performing weight loss exercises, users can learn the pulse information through smart earphones and smart earphone systems, so as to achieve the most suitable heartbeat per minute for burning fat, and then get the best weight loss effect.

1: Smart headset

11: Control module

12: Pulsation measurement module

14: Sound module

15: Communication module

2: mobile device

Claims (13)

A smart earphone includes: an earphone body with an earplug; a control module on the earphone body; a pulsation measuring module on the earplug, the pulsation measuring module as a microphone and electrically connected to the control module Group, when the earplug is placed in an ear canal of a user, the pulsation measuring module is attached to the ear canal to receive a pulsating sound, and a pulsating signal is generated according to the pulsating sound; a sound module is electrically connected to the The control module generates a sound according to a sound signal or generates a warning sound according to a warning sound signal, wherein the sound module generates the warning sound at the same time when the sound is generated; a communication module is electrically connected to the control The module is wirelessly connected to a mobile device, receives the sound signal transmitted by the mobile device and transmits it to the sound generating module via the control module; and a gravity sensor is electrically connected to the control module, the gravity sensor The detector generates a gravity detection result, and transmits the gravity detection result to the control module or to the mobile device via the communication module, wherein the control module determines according to the gravity detection result When the user is in an exercise state, an activation signal is generated and sent to the pulsation measurement module. The pulsation measurement module starts to receive the pulsation sound according to the activation signal, or the mobile device generates the pulsation sound according to the gravity sensor When the result of gravity detection determines that the user is in motion, the activation signal is generated, and the control module receives the activation signal through the communication module and transmits it to the pulsation measurement module, and the pulsation measurement module starts according to the activation signal Receive the pulsating sound. The smart headset according to claim 1, wherein the pulsation measurement module is located in the ear canal of the user or on the side of the opening of the ear canal. The smart headset according to claim 1, wherein the control module generates the warning audio signal when the pulsation signal is abnormal and transmits it to the sound module, or the communication module transmits the pulsation signal to the mobile device, The mobile device generates the warning audio signal when the pulsation signal is abnormal, and the control module receives the warning audio signal via the communication module and transmits it to the sounding module. The smart headset according to claim 1, further comprising: a vibrator electrically connected to the control module, and the control module generates the vibration signal and transmits it to the vibrator when the pulse signal is abnormal, or is it the The communication module transmits the pulsation signal to the mobile device, the mobile device generates a vibration signal when the pulsation signal is abnormal, and the control module receives the vibration signal through the communication module and transmits it to the vibrator. The smart headset according to claim 1, further comprising: an integrated temperature detection module, electrically connected to the control module, detects the user's body temperature to generate an integrated temperature signal, and transmits the integrated temperature signal to the mobile via the communication module The mobile device continuously records the body temperature signal and generates a body temperature abnormality notification when the body temperature signal is abnormal. The smart headset according to claim 1, wherein the gravity sensor generates the gravity detection result and transmits it to the mobile device via the communication module, the mobile device calculates a motion result according to the gravity detection result, and the mobile device sends The exercise result is sent to an electronic device, or the mobile device generates an exercise result sound signal according to the exercise result, the control module receives the exercise result sound signal via the communication module and transmits it to the sound module, the sound module The group generates an exercise result notification based on the exercise result sound signal. The smart headset according to claim 6, wherein when the mobile device determines that the user is in motion based on the gravity detection result, it starts an application, and generates an application message sound signal according to the running result of the application, the The control module receives the application via the communication module The program message sound signal is sent to the sound module, and the sound module generates an application program message sound according to the application program message sound signal. The smart headset according to claim 6, further comprising: a barometer, which is electrically connected to the control module, detects a barometric state and generates a barometric state signal, and the mobile device is based on the gravity detection result and the barometric state The signal calculates the exercise result, and an abnormal value condition of the pulsation signal is set according to the exercise result. A smart headset system, comprising: a cloud host; a mobile device connected to the cloud host; and a smart headset as described in any one of claim 1-8, connected to the mobile device or the cloud host via the communication module , The smart headset transmits a measurement information to the mobile device or the cloud host, and the measurement information at least includes the pulsation signal. A method for prompting physiological information for earphones, comprising: attaching a pulsation measurement module to an ear canal of a user, wherein the pulsation measurement module is a microphone; and a gravity sensor is used to generate a gravity detection result Calculate a motion result based on the gravity detection result; generate an activation signal when judging that the user is in motion based on the gravity detection result; drive the pulsation measurement module to start receiving the pulsation sound according to the activation signal; The pulsation sound generates a pulsation signal; when the pulsation signal is abnormal, a warning sound signal is generated; and based on the warning sound signal, a sound module generates a warning sound. The physiological information prompt method for earphones according to claim 10, wherein, after the step of generating the warning audio signal, it further comprises: generating a vibration with a vibrator according to the warning audio signal. The physiological information prompt method for earphones according to claim 10, wherein the step of calculating the exercise result includes: detecting an air pressure state to generate an air pressure state signal; and according to the gravity detection result and the The air pressure status signal calculates the result of the exercise. The physiological information prompt method for earphones according to claim 10, wherein, when the pulsation measurement module is used to approach the skin of the user, the step further includes: detecting the body temperature of the user to generate an integrated temperature signal ; Record the body temperature signal; and generate a body temperature abnormality notification when the body temperature signal is abnormal.

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