Remote fetal education system with fetal heart monitoring function

A remote and prenatal education technology, applied in transducer circuits, medical science, sensors, etc., can solve the problems of inability to communicate with fetuses, remote interaction, and communication with expectant fathers, and achieve the effect of realizing interaction and overcoming distance obstacles

Inactive Publication Date: 2018-07-10

KONFOONG BIOTECH INT

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AI-Extracted Technical Summary

Problems solved by technology

[0003] In the process of prenatal education, the parents of the fetus will be eager to communicate with the fetus, and the voice from the father-to-be is also important for the good development of the fetus. In most cases, the father-to-be is facing work and busin...

Method used

In sum, in the present embodiment, realized the two-way interaction of fetus and the outside world, on the one hand the sound of fetus is communicated to the outside, on the one hand the v...

Abstract

The invention discloses a remote fetal education system with a fetal heart monitoring function and belongs to the technical field of medical equipment. The system comprises a wearable device, a processing device, a local mobile terminal and a remote mobile terminal; the wearable device is put on at a belly of a pregnant woman for collecting fetal sound which is processed by the processing device and then sent to the local mobile terminal for users to monitor the fetal sound; or the local mobile terminal sends the fetal sound to the remote mobile terminal; the user inputs voice audio to the local mobile terminal by using the remote mobile terminal, and then the processing device connects to obtain the voice audio and processes it into the prenatal audio having a preset frequency, and then the prenatal audio is played by the wearable device. The beneficial effects of the above technical solution are: the wearable device has the functions of collecting fetal sounds and playing prenatal audio, and realizes two-way interaction between the fetus and the outside world; the remote mobile terminal can help the user overcome the distance hindrance and realize interaction with the fetus at any time.

Application Domain

StethoscopeTransducer circuits

Technology Topic

Fetal heart monitoringSpeech sound +6

Image

Examples

Experimental program(1)

Example Embodiment

[0030] The present invention will be further described below with reference to the drawings and specific embodiments, but it is not a limitation of the present invention.

[0031] In a preferred embodiment of the present invention, such as figure 1 As shown, a remote prenatal education system with fetal heart rate monitoring function includes: wearable device 1, processing device 2, local mobile terminal 3, and remote mobile terminal 4. Wearable device 1 is connected to processing device 2, and local mobile terminal 3 is connected to The processing device 2 and the remote mobile terminal 4 realize a wireless communication connection;

[0032] The wearable device 1 is worn on the abdomen of pregnant women during use, is used to collect fetal sounds and output the processing device 2, and is used to play prenatal education audio with a preset frequency;

[0033] The processing device 2 is used to process externally input voice audio to obtain prenatal education audio and output it to the wearable device 1 for playback, and

[0034] Used to perform analog-to-digital conversion processing on the fetal sound collected by the wearable device 1, and send the processed fetal sound to the local mobile terminal 3;

[0035] The local mobile terminal 3 is used for providing the user to monitor the fetal sound and for sending the fetal sound to the remote mobile terminal 4;

[0036] The local mobile terminal 3 is also used to provide the user with input voice audio and send the voice audio to the processing device 2;

[0037] The remote mobile terminal 4 is used to provide the user to monitor the fetal sound, and to provide the user to input voice audio, and send the voice audio to the processing device 2 through the local mobile terminal 3.

[0038] In the above technical solution, the pregnant woman wears the wearable device 1 on the abdomen, the wearable device 1 collects fetal sounds, and outputs the collected fetal heart to the processing device 2, and the external processing device 2 performs analog-to-digital conversion processing on the collected fetal sounds Then it is sent to the local mobile terminal 3 through wireless communication, and the user can monitor the fetal sound through the local mobile terminal 3. When relatives in other places need to listen to the fetal sound, the local mobile terminal 3 can send the fetal sound to the remote mobile terminal 4. Relatives who are away from home can listen to the fetal sound of the fetus through the remote mobile terminal at any time;

[0039] Further, the wearable device 1 also has the function of playing prenatal education audio. The user collects his own voice audio through the local mobile terminal 3 or the remote mobile terminal 4, and sends the voice audio to the processing device through wireless communication through the local mobile terminal 3 2. The processing device 2 processes the voice audio into prenatal education audio that the fetus can accept, and plays it through the wearable device 1, so that relatives who are away from home can convey their voice to the fetus through the remote mobile terminal 4;

[0040] In summary, in this embodiment, the two-way interaction between the fetus and the outside world is realized. On the one hand, the fetus’s voice is communicated to the outside, and on the other hand, the outside sound is communicated to the fetus; at the same time, the remote mobile terminal 4 and the local mobile terminal 3 are used. The docking helps users overcome distance obstacles and realize interaction with the fetus at any time.

[0041] In a preferred embodiment of the present invention, the wearable device 1 includes:

[0042] The collection module 11 is used to collect fetal sound and output it to the processing device 2;

[0043] The first playing module 12 is configured to receive and play the prenatal education audio output by the processing device 2.

[0044] In a preferred embodiment of the present invention, the wearable device 1 further includes:

[0045] The second playback module 13 is connected to the collection module 11 and is used to amplify and play the fetal sound so that the user can directly listen to the fetal sound through the second playback module 13.

[0046] Because the sound used as prenatal education has unique requirements in terms of sound frequency and sound intensity: the sound frequency is best between 100-2000Hz. Sounds below 100Hz may harm the internal organs of the fetus, while sounds higher than 2000Hz will The auditory nerve of the fetus is damaged, and even affects the development of the fetus's brain. Therefore, in this embodiment, a first playing module 12 for playing prenatal education audio and a second playing module 13 for playing fetal sounds are provided on the wearable device 1 to meet different audio playback requirements.

[0047] In a preferred embodiment of the present invention, the processing device 2 includes:

[0048] The first processing module 21 is configured to receive the fetal sound collected by the wearable device 11, and send the fetal sound to the local mobile terminal 3 through wireless communication after analog-to-digital conversion;

[0049] The second processing module 22 is configured to receive the voice audio sent by the local terminal 3 through wireless communication, and process the voice audio into prenatal education audio and output the prenatal education audio to the wearable device 1 to be played by the first playback module 12.

[0050] In a preferred embodiment of the present invention, the processing device 2 further includes:

[0051] The first storage module 23 is connected to the second processing module 22 for storing music and audio suitable for prenatal education;

[0052] The second processing module 22 is also used to process music audio into prenatal education audio and output to the wearable device 1.

[0053] In a preferred embodiment of the present invention, the processing device 2 further includes:

[0054] The second storage module 24 is used to receive the fetal sound collected by the wearable device 1 and store it so as to provide the medical staff for diagnosis based on the fetal sound.

[0055] In a preferred embodiment of the present invention, the processing device 2 and the local mobile terminal 3 are connected by Bluetooth communication.

[0056] In a preferred embodiment of the present invention, the local mobile terminal 3 and the remote mobile terminal 4 are connected through a mobile network.

[0057] In a preferred embodiment of the present invention, the acquisition module 11 is realized by an ultrasonic probe.

[0058] The above descriptions are only preferred embodiments of the present invention, and do not limit the implementation and protection scope of the present invention. For those skilled in the art, they should be able to realize that all equivalents made using the description and illustrations of the present invention are equivalent. The solutions obtained by substitutions and obvious changes should be included in the protection scope of the present invention.

PUM

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Classification and recommendation of technical efficacy words

achieve interaction